使用机器学习和参数化飞行数据预测最大应力

Mike G. Sweet, Samuel Forgerson, Chad deMontfort
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引用次数: 1

摘要

美世工程研究中心(MERC)开发了一种基于神经网络的回归方法,用于使用单个飞行器健康和使用监测(IVHMS)数据预测美国空军HH-60G直升机机身四个结构跟踪位置的每次飞行最大应力值。在HH-60G使用寿命分析中,每次飞行的最大应力用于评估失效标准,因此,对整个机队的最大应力大小和可能性进行准确的估计对于准确的使用寿命确定至关重要。该模型使用参数飞行数据时间历史(来自IVHMS)和应变测量飞机的应力时间历史进行训练。根据应变计在跟踪位置附近的位置不同,采用两种不同的方法从应变信号中得到应力时程。对于其中两个跟踪位置,它们是通过使用整个应变测量飞机的应变计信号收集的全球有限元模型得出的。在另外两个跟踪位置,应变时间历史是由安装在跟踪位置附近的单个应变片得出的。评估了多种回归方法和输入数据配置,以确定一种合适的回归方法,在不过度拟合训练数据的情况下准确预测每次飞行的最大应力。MERC发现,参数化飞行数据和飞机部件应变之间的关系可以使用机器学习回归工具进行高精度开发。实现高水平的准确性需要对独立变量和因变量数据质量进行广泛的审查,并对模型输入进行深思熟虑的考虑。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Predicting a Maximum Stress using Machine Learning and Parametric Flight Data
Mercer Engineering Research Center (MERC) developed a neural network-based regression method for predicting maximum stress per flight values at four structural tracking locations on the United States Air Force HH-60G helicopter airframe using Individual Vehicle Health and Usage Monitoring (IVHMS) data. Maximum stress per flight is utilized when evaluating a failure criterion within the HH-60G service life analysis, so an accurate, fleet-wide estimation of maximum stress magnitude and likelihood is critical for accurate service life determinations. The model was trained using parametric flight data time histories (from IVHMS) and stress time histories from a strain survey aircraft. The stress time histories were developed from the strain signals using two different methods depending on the location of strain gauges in the vicinity of the tracking locations. For two of the tracking locations, they were derived from a global finite element model using a collection of strain gauge signals throughout the strain survey aircraft. At the other two tracking locations, the strain time histories were derived from single strain gauges installed in close proximity to the tracking locations. Multiple regression methods and input data configurations were evaluated in order to identify an appropriate regression method that predicts a maximum stress per flight accurately without over-fitting the training data. MERC identified that the relationship between parametric flight data and aircraft component strain can be exploited to a high level of accuracy using machine learning regression tools. Achieving a high level of accuracy required an extensive review of independent and dependent variable data quality and thoughtful consideration of model inputs.
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