Double event joint location method considering P-wave arrival time system errors

Microseismic (MS) source location is a core technology in MS monitoring that helps to infer the mechanical state of the rock mass and prevent dynamic disasters. However, when considering P-wave arrival time system errors (PATSEs), conventional location methods encounter the problem of high inversion...

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Published inSoil dynamics and earthquake engineering (1984) Vol. 149; p. 106890
Main Authors Jiang, Changbao, Liu, Caiyun, Shang, Xueyi
Format Journal Article
LanguageEnglish
Published Barking Elsevier Ltd 01.10.2021
Elsevier BV
Subjects
Algorithms
Blasting
Data field
Disasters
Earthquakes
Field theory
Joint location
Microseismic monitoring
Microseisms
P waves
P-wave arrival time system error
Seismic activity
Seismology
Source location
Travel time
Microseismic monitoring
Source location
Joint location
Data field
P-wave arrival time system error
Online AccessGet full text
ISSN0267-7261
1879-341X
DOI10.1016/j.soildyn.2021.106890

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Abstract Microseismic (MS) source location is a core technology in MS monitoring that helps to infer the mechanical state of the rock mass and prevent dynamic disasters. However, when considering P-wave arrival time system errors (PATSEs), conventional location methods encounter the problem of high inversion dimensions and do not consider the influence of large P-wave arrival time errors. Therefore, we proposed a low-dimension double event joint location (DEJL) method that considers the PATSEs and introduces data field theory to reduce the influence of large P-wave arrival time errors. First, the P-wave travel-time equation of double events was constructed to eliminate the earthquake occurrence time and PATSEs, and the high-dimension inversion was reduced to a set of equations containing only six parameters. Then, 2000 P-wave arrival time combinations from more than six sensors were selected, and a Newton iterative based algorithm was proposed to solve the location point of each combination. Finally, the location point with the largest potential value of the data field was considered as the location result. The Institute of Mine Seismology acquisition system, placed in the Yongshaba mine in Guizhou Province, China, was selected to conduct the tests. P-wave arrival time datasets were obtained from two synthetic locations and eight blasting events. The results showed that the average location error of the blasting events using the proposed method is 32.59 m, which is lower than that of the homogeneous velocity-based location results. Thus, we determined that the proposed method offers a good MS location accuracy and broad application potential. •A double event joint location (DEJL) method is proposed.•The DEJL method considers P-wave arrival time system errors.•The DEJL method eliminates influence of large P-wave arrival time system errors.•The DEJL method shows a broad application prospect in microseismic event locations.
AbstractList Microseismic (MS) source location is a core technology in MS monitoring that helps to infer the mechanical state of the rock mass and prevent dynamic disasters. However, when considering P-wave arrival time system errors (PATSEs), conventional location methods encounter the problem of high inversion dimensions and do not consider the influence of large P-wave arrival time errors. Therefore, we proposed a low-dimension double event joint location (DEJL) method that considers the PATSEs and introduces data field theory to reduce the influence of large P-wave arrival time errors. First, the P-wave travel-time equation of double events was constructed to eliminate the earthquake occurrence time and PATSEs, and the high-dimension inversion was reduced to a set of equations containing only six parameters. Then, 2000 P-wave arrival time combinations from more than six sensors were selected, and a Newton iterative based algorithm was proposed to solve the location point of each combination. Finally, the location point with the largest potential value of the data field was considered as the location result. The Institute of Mine Seismology acquisition system, placed in the Yongshaba mine in Guizhou Province, China, was selected to conduct the tests. P-wave arrival time datasets were obtained from two synthetic locations and eight blasting events. The results showed that the average location error of the blasting events using the proposed method is 32.59 m, which is lower than that of the homogeneous velocity-based location results. Thus, we determined that the proposed method offers a good MS location accuracy and broad application potential. •A double event joint location (DEJL) method is proposed.•The DEJL method considers P-wave arrival time system errors.•The DEJL method eliminates influence of large P-wave arrival time system errors.•The DEJL method shows a broad application prospect in microseismic event locations.
Microseismic (MS) source location is a core technology in MS monitoring that helps to infer the mechanical state of the rock mass and prevent dynamic disasters. However, when considering P-wave arrival time system errors (PATSEs), conventional location methods encounter the problem of high inversion dimensions and do not consider the influence of large P-wave arrival time errors. Therefore, we proposed a low-dimension double event joint location (DEJL) method that considers the PATSEs and introduces data field theory to reduce the influence of large P-wave arrival time errors. First, the P-wave travel-time equation of double events was constructed to eliminate the earthquake occurrence time and PATSEs, and the high-dimension inversion was reduced to a set of equations containing only six parameters. Then, 2000 P-wave arrival time combinations from more than six sensors were selected, and a Newton iterative based algorithm was proposed to solve the location point of each combination. Finally, the location point with the largest potential value of the data field was considered as the location result. The Institute of Mine Seismology acquisition system, placed in the Yongshaba mine in Guizhou Province, China, was selected to conduct the tests. P-wave arrival time datasets were obtained from two synthetic locations and eight blasting events. The results showed that the average location error of the blasting events using the proposed method is 32.59 m, which is lower than that of the homogeneous velocity-based location results. Thus, we determined that the proposed method offers a good MS location accuracy and broad application potential.
ArticleNumber 106890
Author Liu, Caiyun
Jiang, Changbao
Shang, Xueyi
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Keywords Microseismic monitoring
Source location
Joint location
Data field
P-wave arrival time system error
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Snippet Microseismic (MS) source location is a core technology in MS monitoring that helps to infer the mechanical state of the rock mass and prevent dynamic...
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elsevier
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StartPage 106890
SubjectTerms Algorithms
Blasting
Data field
Disasters
Earthquakes
Field theory
Joint location
Microseismic monitoring
Microseisms
P waves
P-wave arrival time system error
Seismic activity
Seismology
Source location
Travel time
Title Double event joint location method considering P-wave arrival time system errors
URI https://dx.doi.org/10.1016/j.soildyn.2021.106890
https://www.proquest.com/docview/2568032582
Volume 149
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