The Underground Explosion Point Measurement Method Based on High-Precision Location of Energy Focus

The Underground Explosion Point Measurement Method Based on High-Precision Location of Energy Focus

Source positioning based on energy time-inverse focus is a hot subject in the sphere of shallow underground source positioning. Due to the grave wave group aliasing and the complex, irregular geological structure typical of the shallow underground explosion, the reconstruction accuracy of the energy...

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Main Authors: Jian Li, Feifei Zhao, Xiaoliang Wang, Fengcai Cao, Xingcheng Han
Format: Article
Language:English
Published: IEEE 2020-01-01
Series:IEEE Access
Subjects:
Position measurement
energy field reconstruction
underground explosion
Online Access:https://ieeexplore.ieee.org/document/9163341/
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spelling doaj-d537977b9e824a38aa603f22d03886572021-03-30T03:32:27ZengIEEEIEEE Access2169-35362020-01-01816598916600210.1109/ACCESS.2020.30154869163341The Underground Explosion Point Measurement Method Based on High-Precision Location of Energy FocusJian Li0https://orcid.org/0000-0002-2282-9624Feifei Zhao1https://orcid.org/0000-0001-7163-9897Xiaoliang Wang2https://orcid.org/0000-0002-6228-9028Fengcai Cao3https://orcid.org/0000-0001-5959-5035Xingcheng Han4https://orcid.org/0000-0002-4604-2690National Key Laboratory of Electronic Measurement Technology, North University of China, Taiyuan, ChinaShanxi Key Laboratory of Information Detection and Processing, North University of China, Taiyuan, ChinaShanxi Key Laboratory of Information Detection and Processing, North University of China, Taiyuan, ChinaShanxi Key Laboratory of Information Detection and Processing, North University of China, Taiyuan, ChinaShanxi Key Laboratory of Information Detection and Processing, North University of China, Taiyuan, ChinaSource positioning based on energy time-inverse focus is a hot subject in the sphere of shallow underground source positioning. Due to the grave wave group aliasing and the complex, irregular geological structure typical of the shallow underground explosion, the reconstruction accuracy of the energy focus is low and thus the recognition of the focus is a difficult task, ultimately leading to a low accuracy of source positioning. To address the above problems, this article proposes a method based on deep learning energy focus recognition, whereby the process of recognizing and positioning the energy focus in an energy field is made equivalent to the end-to-end feature extraction of the energy field-energy focus. The time-variant characteristics of explosive vibration signals are put to use in the construction of an adaptive time window. First, within the time window and by combining cross-correlation and autocorrelation operations, a 3D energy field image sequence in the time-space domain is produced by grouped energy synthesis; second, a densely connected 3DCNN network is built and, through multiple layer span layer splicing, a higher repetitive use is made of the focus point features in the energy field images; third, a spatial pyramid pooling network is used to extract multi-scale features from different focus areas, which helps achieve high-precision focus recognition. Finally, numerical simulations and field tests were conducted.The results demonstrated that compared with the quantum particle swarm optimization (QPSO)-based energy focus search method, the proposed one is more effectively in recognizing the coordinates of the focus in the energy field, thus allowing high-precision localization of shallow underground sources. This method is of some engineering application value in the field of underground source positioning.https://ieeexplore.ieee.org/document/9163341/Position measurementenergy field reconstructionunderground explosion
collection DOAJ
language English
format Article
sources DOAJ
author Jian Li
Feifei Zhao
Xiaoliang Wang
Fengcai Cao
Xingcheng Han
spellingShingle Jian Li
Feifei Zhao
Xiaoliang Wang
Fengcai Cao
Xingcheng Han
The Underground Explosion Point Measurement Method Based on High-Precision Location of Energy Focus
IEEE Access
Position measurement
energy field reconstruction
underground explosion
author_facet Jian Li
Feifei Zhao
Xiaoliang Wang
Fengcai Cao
Xingcheng Han
author_sort Jian Li
title The Underground Explosion Point Measurement Method Based on High-Precision Location of Energy Focus
title_short The Underground Explosion Point Measurement Method Based on High-Precision Location of Energy Focus
title_full The Underground Explosion Point Measurement Method Based on High-Precision Location of Energy Focus
title_fullStr The Underground Explosion Point Measurement Method Based on High-Precision Location of Energy Focus
title_full_unstemmed The Underground Explosion Point Measurement Method Based on High-Precision Location of Energy Focus
title_sort underground explosion point measurement method based on high-precision location of energy focus
publisher IEEE
series IEEE Access
issn 2169-3536
publishDate 2020-01-01
description Source positioning based on energy time-inverse focus is a hot subject in the sphere of shallow underground source positioning. Due to the grave wave group aliasing and the complex, irregular geological structure typical of the shallow underground explosion, the reconstruction accuracy of the energy focus is low and thus the recognition of the focus is a difficult task, ultimately leading to a low accuracy of source positioning. To address the above problems, this article proposes a method based on deep learning energy focus recognition, whereby the process of recognizing and positioning the energy focus in an energy field is made equivalent to the end-to-end feature extraction of the energy field-energy focus. The time-variant characteristics of explosive vibration signals are put to use in the construction of an adaptive time window. First, within the time window and by combining cross-correlation and autocorrelation operations, a 3D energy field image sequence in the time-space domain is produced by grouped energy synthesis; second, a densely connected 3DCNN network is built and, through multiple layer span layer splicing, a higher repetitive use is made of the focus point features in the energy field images; third, a spatial pyramid pooling network is used to extract multi-scale features from different focus areas, which helps achieve high-precision focus recognition. Finally, numerical simulations and field tests were conducted.The results demonstrated that compared with the quantum particle swarm optimization (QPSO)-based energy focus search method, the proposed one is more effectively in recognizing the coordinates of the focus in the energy field, thus allowing high-precision localization of shallow underground sources. This method is of some engineering application value in the field of underground source positioning.
topic Position measurement
energy field reconstruction
underground explosion
url https://ieeexplore.ieee.org/document/9163341/
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AT xiaoliangwang theundergroundexplosionpointmeasurementmethodbasedonhighprecisionlocationofenergyfocus
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AT feifeizhao undergroundexplosionpointmeasurementmethodbasedonhighprecisionlocationofenergyfocus
AT xiaoliangwang undergroundexplosionpointmeasurementmethodbasedonhighprecisionlocationofenergyfocus
AT fengcaicao undergroundexplosionpointmeasurementmethodbasedonhighprecisionlocationofenergyfocus
AT xingchenghan undergroundexplosionpointmeasurementmethodbasedonhighprecisionlocationofenergyfocus
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