Intelligent target recognition for distributed acoustic sensors by using both manual and deep features

Huijuan Wu; Chaoqun Wang; Xinyu Liu; DengKe Gan; Yimeng Liu; Yunjiang Rao; Yunjiang Rao; Abdulafeez Olawale Olaribigbe

doi:10.1364/AO.431791

Applied Optics
Vol. 60,
Issue 23,
pp. 6878-6887
(2021)
•https://doi.org/10.1364/AO.431791

Intelligent target recognition for distributed acoustic sensors by using both manual and deep features

Huijuan Wu, Chaoqun Wang, Xinyu Liu, DengKe Gan, Yimeng Liu, Yunjiang Rao, and Abdulafeez Olawale Olaribigbe

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Huijuan Wu, Chaoqun Wang, Xinyu Liu, DengKe Gan, Yimeng Liu, Yunjiang Rao, and Abdulafeez Olawale Olaribigbe, "Intelligent target recognition for distributed acoustic sensors by using both manual and deep features," Appl. Opt. 60, 6878-6887 (2021)

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Related Topics
Table of Contents Category
- Fiber Optics, Fiber Sensors, and Optical Communications
Optics & Photonics Topics
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The topics in this list come from the Optics and Photonics Topics applied to this article.

About this Article
History
- Original Manuscript: May 21, 2021
- Revised Manuscript: July 4, 2021
- Manuscript Accepted: July 5, 2021
- Published: August 4, 2021

Abstract

Effective information mining of fiber-optic distributed acoustic sensors (DAS) is so important that it attracts more and more public attention, and various manual and deep feature extraction methods have been developed. However, either way it has limits; for example, the manual features contain insufficient information, and the deep features could be unreliable because of the overfitting problem. Thus, in this paper, to avoid the disadvantages of each and make full use of the effective information carried by DAS signals, an intelligent target recognition method by utilizing both manual and deep features is proposed. The manual features are first extracted in the time domain, frequency domain, semantic domain, and from dynamic models, which are fused with the deep features extracted by a four-layer 1D convolutional neural network (CNN) through feature engineering. The features are ranked and then selected by a combined weighting method of analysis of variance and maximum information coefficient. Then finally, an optimal classifier is selected by comparing support vector machine, extreme gradient boost, random forest, and native Bayesian. In the test with real field data, four types of features, which include the manual features, the CNN features, and the combined features without and with selection, are compared with these different classifiers. As a result, it shows the combined features without selection can improve the identification ability of DAS compared with the recognition with only manual or deep features. The combined features with selection can further improve the computation efficiency and save up to 90% of time with a performance degradation of less than 1%.

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Data underlying the results presented in this paper are not publicly available at this time but may be obtained from the authors upon reasonable request.

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Convolution Kernel Size	Number of Convolution Kernels	Convolution Kernel Step Size	Convolution Padding	Pooled Kernel Size	Pooled Nuclear Stride
$1 \times 5$	16	1	2	$1 \times 5$	5
$1 \times 3$	32	1	1	$1 \times 2$	2
$1 \times 3$	64	1	1	$1 \times 2$	2
$1 \times 3$	128	1	1	$1 \times 3$	2

Event Type	Database (Signal Samples)	Event Label
Background noise	2293	1
Manual digging	3884	2
Mechanical excavation	1501	3
Traffic interference	2470	4
Factory noise	943	5

Classifiers	Features	Precision	Accuracy	F1-Score
SVM	Manual features	0.9386	0.9312	0.9292
	CNN features	0.9484	0.9471	0.9382
	Combined features without selection	0.9596	0.9588	0.9563
	Combined features with selection	0.9544	0.9522	0.9463
XGB	Manual features	0.9455	0.9468	0.9387
	CNN features	0.9512	0.9492	0.9413
	Combined features without selection	0.9610	0.9609	0.9565
	Combined features with selection	0.9534	0.9522	0.9451
RF	Manual features	0.9440	0.9366	0.9262
	CNN features	0.9347	0.9327	0.9205
	Combined features without selection	0.9473	0.9450	0.9394
	Combined features with selection	0.9486	0.9450	0.9378
NB	Manual features	0.8441	0.86230	0.8430
	CNN features	0.8267	0.8468	0.8349
	Combined features without selection	0.8737	0.8951	0.8834
	Combined features with selection	0.8743	0.8924	0.8830

Classifiers		SVM	XGB	RF	NB
w/o selection	Predicting time(s)	11.58	6.402	4.248	5.116
w selection	Predicting time(s)	7.769	0.688	2.043	0.239
Manual features	Predicting time(s)	5.310	0.280	1.57	0.122
CNN features	Predicting time(s)	0.080

Convolution Kernel Size	Number of Convolution Kernels	Convolution Kernel Step Size	Convolution Padding	Pooled Kernel Size	Pooled Nuclear Stride
$1 \times 5$	16	1	2	$1 \times 5$	5
$1 \times 3$	32	1	1	$1 \times 2$	2
$1 \times 3$	64	1	1	$1 \times 2$	2
$1 \times 3$	128	1	1	$1 \times 3$	2

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Applied Optics