航空学报 > 2024, Vol. 45 Issue (5): 529957-529957   doi: 10.7527/S1000-6893.2024.29957

基于BP神经网络的试飞训练安全性量化模型

马菲1,2, 张琼1,3(), 赖培军1, 岳一笛1   

  1. 1.中国商飞 民用飞机试飞中心, 上海 200232
    2.西北工业大学 航空学院, 西安 710072
    3.南京航空航天大学 民航学院, 南京 210016
  • 收稿日期:2023-12-08 修回日期:2023-12-11 接受日期:2024-01-05 出版日期:2024-03-15 发布日期:2024-01-11
  • 通讯作者: 张琼 E-mail:withnoend@sina.com
  • 基金资助:
    国家级项目

BP neural network⁃based quantitative classification model for safety in experimental flight training

Fei MA1,2, Qiong ZHANG1,3(), Peijun LAI1, Yidi YUE1   

  1. 1.Flight Test Center,Commercial Aircraft Corporation of China,Shanghai 200232,China
    2.School of Aeronautics,Northwestern Polytechnical University,Xi’an 710072,China
    3.College of Civil Aviation,Nanjing University of Aeronautics and Astronautics,Nanjing 210016,China
  • Received:2023-12-08 Revised:2023-12-11 Accepted:2024-01-05 Online:2024-03-15 Published:2024-01-11
  • Contact: Qiong ZHANG E-mail:withnoend@sina.com
  • Supported by:
    National Level Project

摘要:

为提升试飞员在航空试验飞行过程中的飞行安全、降低试验飞行的风险等级,研究基于BP神经网络的试验飞行训练安全性分级量化分析模型。以人因工程的人、机、环为切入,分析试验飞行训练过程中影响试飞安全的因素,并选取人、试飞训练科目及环境三部分重要因素,建立试验飞行训练过程中的安全性分级量化分析指标体系。经人因工程指标量化处理后,由于融合的数据类型相似度较低,因此采用BP神经网络构建试验飞行训练安全性分级量化分析模型,经模型训练、测试后,输出试验飞行训练的安全性分级量化等级。利用定制的接触式采集设备和非接触式面部识别系统,采集试飞员执行试飞科目训练时身体节律数据,分析训练过程中科目复杂度和难度对试飞员心理特征和生理特征的影响,从而建立量化指标和预警指标,以此优化试验飞行训练课程、提高训练品质,保障试飞安全。试验表明,该模型所得试验飞行训练过程中的安全性分级量化模型输出偏差小于2%,模型预测结果与训练过程中实际风险等级基本吻合,可有效地用于试飞训练过程中风险预警,提高试飞员训练品质,为实际试飞安全提供保障。

关键词: 人因工程, BP神经网络, 风险预警, 试验飞行训练过程, 分级量化

Abstract:

To enhance the safety of test pilots during aviation experimental flights and reduce the risk level of experimental flights, a quantitative analysis model for the safety classification of experimental flight training is developed based on the Back-Propagation (BP) neural network. Adopting a human factor engineering perspective, the factors influencing test flight safety during the experimental flight training process are analyzed. Three key components, namely the human factor, aircraft factor, and environmental factor, are chosen for the analysis. A structured system of quantitative analysis indicators for safety classification during the experimental flight training process is established, focusing on the pivotal elements of human factors, specific experimental training subjects, and environmental conditions. After quantifying the human factors engineering indicators, due to the relatively low similarity in the fused data types, the BP neural network is employed to construct a quantitative analysis model for safety classification in experimental flight training. Following model training and testing, a quantified safety classification level for the experimental flight training process is output. Utilizing customized tactile acquisition devices and a non-contact facial recognition system, the physiological rhythm data of test pilots during the execution of experimental flight training subjects are collected. The analysis focuses on understanding the impact of the complexity and difficulty of training subjects on the psychological and physiological characteristics of test pilots. On this basis, the quantitative metrics and warning indicators are established, allowing for optimization of experimental flight training subjects, improvement of training quality, and the assurance of test flight safety. The experiments indicate that the output deviation of the quantitative classification model for safety in the experimental flight training process is less than 2%. The model’s predicted results closely align with the actual risk levels observed during the training process, showing that the model proposed can be effectively utilized for risk warning during experimental flight training, and thereby enhance the quality of pilot training and provide reliable safeguard for actual test flight safety.

Key words: human factors engineering, BP neural network, risk prediction, experimental flight training process, quantitative classification

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