Deep learning method for predicting electromagnetic emission spectrum of aerospace equipment

IF 1.4 4区 工程技术 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC
Yuting Zhang
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Abstract

This paper proposes a deep learning method to predict the electromagnetic emission spectrum in the electromagnetic compatibility (EMC) test of aerospace products. A threshold-based data decomposition method is used to propose the spike signal, reconstruct the original test data, and solve the contradiction between the overfitting and prediction accuracy of the deep learning method to deal with the EMC test spectrum. Using a long short-term memory neural network architecture for predicting electromagnetic emission spectrum, the Bayesian optimization method is used to optimize the network hyperparameter, and the acquisition function is introduced into the loss function to improve the comprehensive training optimization of deep learning network. Apply the method to three numerical examples: signal line current conduction emission, power line voltage conduction emission, and electric field radiation emission. The analysis results indicate that at a 95% confidence level, the predicted electromagnetic emission spectrum is basically consistent with the test results. The prediction results can be used as the basis for EMC evaluation of aerospace electronic equipment.

Abstract Image

预测航空航天设备电磁发射频谱的深度学习方法
本文提出了一种深度学习方法,用于预测航空航天产品电磁兼容(EMC)测试中的电磁发射频谱。采用基于阈值的数据分解方法提出尖峰信号,重构原始测试数据,解决了深度学习方法处理电磁兼容(EMC)测试频谱的过拟合与预测精度之间的矛盾。利用长短期记忆神经网络架构预测电磁辐射频谱,采用贝叶斯优化方法优化网络超参数,并在损失函数中引入获取函数,提高深度学习网络的综合训练优化能力。将该方法应用于三个数值实例:信号线电流传导发射、电力线电压传导发射和电场辐射发射。分析结果表明,在 95% 的置信度下,预测的电磁发射光谱与测试结果基本一致。预测结果可作为航空航天电子设备电磁兼容性评估的依据。
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来源期刊
Iet Science Measurement & Technology
Iet Science Measurement & Technology 工程技术-工程:电子与电气
CiteScore
4.30
自引率
7.10%
发文量
41
审稿时长
7.5 months
期刊介绍: IET Science, Measurement & Technology publishes papers in science, engineering and technology underpinning electronic and electrical engineering, nanotechnology and medical instrumentation.The emphasis of the journal is on theory, simulation methodologies and measurement techniques. The major themes of the journal are: - electromagnetism including electromagnetic theory, computational electromagnetics and EMC - properties and applications of dielectric, magnetic, magneto-optic, piezoelectric materials down to the nanometre scale - measurement and instrumentation including sensors, actuators, medical instrumentation, fundamentals of measurement including measurement standards, uncertainty, dissemination and calibration Applications are welcome for illustrative purposes but the novelty and originality should focus on the proposed new methods.
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