基于超短飞秒光栅阵列和人工神经网络的卫星结构健康监测研究

IF 2.6 3区计算机科学 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC

Optical Fiber Technology Pub Date : 2024-09-24 DOI:10.1016/j.yofte.2024.103981

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引用次数: 0

摘要

航天器和在轨卫星的安全非常重要，需要进行结构健康监测。目前，现有技术受载荷限制，难以实现。本文提出了一种在掺氧化物光纤上刻蚀超短飞秒光栅阵列并结合多层人工神经网络来检测和定位卫星损伤的可行方法。本文设计了一种具有高鲁棒性的掺氧化物光纤，并利用飞秒激光逐点刻写技术在光纤上制作了超短光栅阵列。通过数值模拟和物理实验研究了冲击速度和角度对冲击响应的影响。随后，对卫星进行了反复撞击实验，获得了二维卷积神经网络的训练数据集和测试数据集。采用对称约定内核的网络定位精度为 88.12%，在边界区域的表现更好；采用非对称约定内核的网络结构定位精度为 90.31%，在中间区域的表现更好。

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Research on satellite structural health monitoring based on ultrashort femtosecond grating array and artificial neural network

The safety of spacecraft and satellite in orbit is very important, and structural health monitoring is needed. At present, the existing technology is limited by load and difficult to realize. In this paper, we propose a feasible method to detect and locate the damage of satellite by combining ultrashort femtosecond grating array inscribed on oxide-doped fiber with multilayer artificial neural network. An oxide-doped fiber with high robustness is designed, and ultrashort grating arrays are fabricated on the fiber by femtosecond laser point-by-point writing technology. The effects of impactor velocity and angle on impact response was investigated by numerical simulations and physical experiments. Subsequently, repeated impact experiments were conducted on the satellite to obtain the training dataset and testing dataset for two-dimensional convolutional neural network. The network with symmetric convention kernels has an 88.12% localization accuracy and a better performance in boundary region, and the network architecture with asymmetric convention kernels has a 90.31% accuracy and a better performance in middle region.

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来源期刊

Optical Fiber Technology 工程技术-电信学

CiteScore

4.80

自引率

11.10%

发文量

327

审稿时长

63 days

期刊介绍： Innovations in optical fiber technology are revolutionizing world communications. Newly developed fiber amplifiers allow for direct transmission of high-speed signals over transcontinental distances without the need for electronic regeneration. Optical fibers find new applications in data processing. The impact of fiber materials, devices, and systems on communications in the coming decades will create an abundance of primary literature and the need for up-to-date reviews. Optical Fiber Technology: Materials, Devices, and Systems is a new cutting-edge journal designed to fill a need in this rapidly evolving field for speedy publication of regular length papers. Both theoretical and experimental papers on fiber materials, devices, and system performance evaluation and measurements are eligible, with emphasis on practical applications.