基于图卷积神经网络的飞机起落架载荷预测

IF 4.3 2区综合性期刊 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Sensors Journal Pub Date : 2024-12-09 DOI:10.1109/JSEN.2024.3510549

Du Wang;Mingli Dong;Xiaoping Lou;Lianqing Zhu;Mingxin Yu;Jiabin Xia;Yiqun Zhang;Chaofan Deng;Yunhong Zhu;Le Wang

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引用次数: 0

摘要

本文利用图卷积神经网络（GCNs）提出了一种精确的飞机起落架载荷估计模型，该模型利用结构应变分布数据预测载荷。建立地基实验系统，在起落架关键点部署光纤光栅应变传感器，采集各种工况下的应变数据，用于模型训练。GCN模型经过应变-负载映射训练和测试，使用最大相对误差、平均相对误差和标准偏差评估预测精度和稳定性。结果显示了稳定和精确的预测，X、Y和Z负荷预测的最大相对误差分别为5.18%、4.15%和3.57%，平均相对误差分别为1.58%、0.61%和0.75%，标准差分别为0.59、0.74和0.46 n。和多层感知器（MLP）]强调了GCN模型优越的预测精度。这项工作在飞机结构健康监测方面具有重要的应用潜力。

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Enhanced Load Prediction for Aircraft Landing Gear Utilizing Graph Convolutional Neural Network

This study presents an accurate aircraft landing gear load estimation model leveraging graph convolutional neural networks (GCNs), which predicts loads from structural strain distribution data. A ground-based experimental system is established, deploying fiber-grating strain sensors at key landing gear points to gather strain data under various operating conditions for model training. The GCN model undergoes strain-to-load mapping training and testing, with prediction accuracy and stability evaluated using maximum relative error, average relative error, and standard deviation. Results showcase stable and precise predictions, with X, Y, and Z load predictions achieving maximum relative errors of 5.18%, 4.15%, and 3.57%, respectively, and average relative errors of 1.58%, 0.61%, and 0.75%, respectively, alongside low standard deviations of 0.59, 0.74, and 0.46 N. Comparative analyses against multiple linear regression and advanced neural networks [long short-term memory (LSTM), convolutional neural network (CNN), and multilayer perceptron (MLP)] underscore the GCN model’s superior prediction accuracy. This work holds significant potential for applications in aircraft structural health monitoring.

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来源期刊

IEEE Sensors Journal 工程技术-工程：电子与电气

CiteScore

7.70

自引率

14.00%

发文量

2058

审稿时长

5.2 months

期刊介绍： The fields of interest of the IEEE Sensors Journal are the theory, design , fabrication, manufacturing and applications of devices for sensing and transducing physical, chemical and biological phenomena, with emphasis on the electronics and physics aspect of sensors and integrated sensors-actuators. IEEE Sensors Journal deals with the following: -Sensor Phenomenology, Modelling, and Evaluation -Sensor Materials, Processing, and Fabrication -Chemical and Gas Sensors -Microfluidics and Biosensors -Optical Sensors -Physical Sensors: Temperature, Mechanical, Magnetic, and others -Acoustic and Ultrasonic Sensors -Sensor Packaging -Sensor Networks -Sensor Applications -Sensor Systems: Signals, Processing, and Interfaces -Actuators and Sensor Power Systems -Sensor Signal Processing for high precision and stability (amplification, filtering, linearization, modulation/demodulation) and under harsh conditions (EMC, radiation, humidity, temperature); energy consumption/harvesting -Sensor Data Processing (soft computing with sensor data, e.g., pattern recognition, machine learning, evolutionary computation; sensor data fusion, processing of wave e.g., electromagnetic and acoustic; and non-wave, e.g., chemical, gravity, particle, thermal, radiative and non-radiative sensor data, detection, estimation and classification based on sensor data) -Sensors in Industrial Practice