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基于改进 YOLOv4 的光纤振动信号识别方法。

Optical Fiber Vibration Signal Identification Method Based on Improved YOLOv4.

机构信息

Xinjiang Key Laboratory of Signal Detection and Processing, School of Information Science and Engineering, Xinjiang University, Urumqi 830017, China.

出版信息

Sensors (Basel). 2022 Nov 28;22(23):9259. doi: 10.3390/s22239259.

DOI:10.3390/s22239259
PMID:36501965
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9736507/
Abstract

In the traditional peripheral-security-early-warning system, the endpoint detection and pattern recognition of the signals generated by the distributed optical fiber vibration sensors is completed step-by-step and in an orderly manner. The method by which these two processes may be placed end-to-end in a network model and processed simultaneously to improve work efficiency has increasingly become the focus of research. In this paper, the target detection algorithm combines the endpoint-detection and pattern-recognition processes of the vibration signal, which can not only quickly locate the start and end vibration positions of the signal but also accurately identify a certain type of signal. You Only Look Once v4 (YOLOv4) is one of the most advanced target detection algorithms, achieving the optimal balance of speed and accuracy. To reduce the complexity of the YOLOv4 model and solve the dataset's unbalanced sample classification problem, we use a deep separable convolution (DSC) network and a focal loss function to improve the YOLOv4 model. In this paper, the five kinds of signals collected in real-time are visualized as two different datasets in oscillograph and time-frequency diagrams as detection objects. According to the experimental results, we obtained 98.50% and 93.48% mean Average Precision (mAP) and 84.8 and 69.9 frames per second (FPS), respectively, which are improved compared to YOLOv4. Comparing the improved algorithm with other optical fiber vibration signal recognition algorithms, the mAP and FPS values were improved, and the detection speed was about 20 times faster than that of other algorithms. The improved algorithm in this paper can quickly and accurately identify the vibration signal of external intrusion, reduce the false-alarm rate of the early-warning system, and improve the real-time detection rate of the system while ensuring high recognition accuracy.

摘要

在传统的周界安防预警系统中,分布式光纤振动传感器产生的信号的端点检测和模式识别是逐步有序完成的。将这两个过程以端到端的方式放置在网络模型中并同时进行处理以提高工作效率的方法,越来越成为研究的焦点。本文将目标检测算法结合了振动信号的端点检测和模式识别过程,不仅可以快速定位信号的起始和结束振动位置,而且可以准确识别某种类型的信号。你只需看一次 v4(YOLOv4)是最先进的目标检测算法之一,在速度和准确性之间实现了最佳平衡。为了降低 YOLOv4 模型的复杂性并解决数据集不平衡样本分类问题,我们使用深度可分离卷积(DSC)网络和焦点损失函数来改进 YOLOv4 模型。在本文中,实时采集的五种信号作为检测对象,分别以示波器和时频图的形式可视化两种不同的数据集。根据实验结果,我们分别获得了 98.50%和 93.48%的平均精度(mAP)和 84.8 和 69.9 帧每秒(FPS),与 YOLOv4 相比均有所提高。将改进后的算法与其他光纤振动信号识别算法进行比较,mAP 和 FPS 值均有所提高,检测速度比其他算法快约 20 倍。本文提出的改进算法可以快速准确地识别外部入侵的振动信号,降低预警系统的误报率,在保证高识别精度的同时提高系统的实时检测率。

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