CNN-KA: A Hybrid P-phase Picking Method for Microseismic Source Location in Deep Mine with Complex Geological Conditions

CNN-KA: A Hybrid P-phase Picking Method for Microseismic Source Location in Deep Mine with Complex Geological Conditions

Microseismic (MS) technology is one of the effective methods for engineering fracture monitoring, and has been widely used in coal mining. Accurate P-phase arrivals are critical for improving accuracy of source locations and MS parameters. In this study, a multi-step method (CNN-KA) combining convol...

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Veröffentlicht in:IEEE transactions on geoscience and remote sensing 2025-01, p.1-1
Hauptverfasser: Zhang, Yongshu, Li, Lianchong, Mu, Wenqiang, Wei, Tingshuang, Wang, Xin, Yu, Guofeng
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Accuracy
Coal
Coal mine
Coal mining
Convolutional neural networks
Deep learning
Excavation
Face recognition
Geology
Microseismic monitoring
Mining-induced data
Monitoring
P-phase arrival
Rocks
Sensors
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Li, Lianchong
Mu, Wenqiang
Wei, Tingshuang
Wang, Xin
Yu, Guofeng
description Microseismic (MS) technology is one of the effective methods for engineering fracture monitoring, and has been widely used in coal mining. Accurate P-phase arrivals are critical for improving accuracy of source locations and MS parameters. In this study, a multi-step method (CNN-KA) combining convolutional neural network (CNN) combined, K-means and Akaike information criterion (AIC) is proposed. Firstly, CNN is applied to recognize mining-induced waveforms of rock fractures. Secondly, maximum overlapping discrete wavelet transform and multi-resolution analysis are integrated to denoise for acquired waveforms. Subsequently, a new picker was developed by introducing K-mean clustering to AIC. Finally, performance of the proposed CNN-KA was evaluated with open-access and in-field data. Combined with software development, the proposed method was applied in 12123 working face of Paner coal mine in Anhui Province, China. The results show that accuracy of CNN-KA in recognizing mining-induced rock fracturing events is 98.11%. The mean absolute error of CNN-KA is 0.0915s at 200Hz frequency, which is 86.65% lower than STA/LTA (short-term average to long-term average, one of the most commonly used in MS technology). The error of picking and positioning are 3.7ms and 10.89m respectively at 5000Hz frequency. MS source parameters based on CNN-KA was effectively used to interpret the abnormal dynamic response of the roof stratum in 12123 working face of Paner coal mine, which was confirmed by real-time mine pressure and design data of the residual coal pillars. The results can be further used for calculating precise MS source parameters and early warning of engineering geohazards.
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Accurate P-phase arrivals are critical for improving accuracy of source locations and MS parameters. In this study, a multi-step method (CNN-KA) combining convolutional neural network (CNN) combined, K-means and Akaike information criterion (AIC) is proposed. Firstly, CNN is applied to recognize mining-induced waveforms of rock fractures. Secondly, maximum overlapping discrete wavelet transform and multi-resolution analysis are integrated to denoise for acquired waveforms. Subsequently, a new picker was developed by introducing K-mean clustering to AIC. Finally, performance of the proposed CNN-KA was evaluated with open-access and in-field data. Combined with software development, the proposed method was applied in 12123 working face of Paner coal mine in Anhui Province, China. The results show that accuracy of CNN-KA in recognizing mining-induced rock fracturing events is 98.11%. The mean absolute error of CNN-KA is 0.0915s at 200Hz frequency, which is 86.65% lower than STA/LTA (short-term average to long-term average, one of the most commonly used in MS technology). The error of picking and positioning are 3.7ms and 10.89m respectively at 5000Hz frequency. MS source parameters based on CNN-KA was effectively used to interpret the abnormal dynamic response of the roof stratum in 12123 working face of Paner coal mine, which was confirmed by real-time mine pressure and design data of the residual coal pillars. 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Accurate P-phase arrivals are critical for improving accuracy of source locations and MS parameters. In this study, a multi-step method (CNN-KA) combining convolutional neural network (CNN) combined, K-means and Akaike information criterion (AIC) is proposed. Firstly, CNN is applied to recognize mining-induced waveforms of rock fractures. Secondly, maximum overlapping discrete wavelet transform and multi-resolution analysis are integrated to denoise for acquired waveforms. Subsequently, a new picker was developed by introducing K-mean clustering to AIC. Finally, performance of the proposed CNN-KA was evaluated with open-access and in-field data. Combined with software development, the proposed method was applied in 12123 working face of Paner coal mine in Anhui Province, China. The results show that accuracy of CNN-KA in recognizing mining-induced rock fracturing events is 98.11%. The mean absolute error of CNN-KA is 0.0915s at 200Hz frequency, which is 86.65% lower than STA/LTA (short-term average to long-term average, one of the most commonly used in MS technology). The error of picking and positioning are 3.7ms and 10.89m respectively at 5000Hz frequency. MS source parameters based on CNN-KA was effectively used to interpret the abnormal dynamic response of the roof stratum in 12123 working face of Paner coal mine, which was confirmed by real-time mine pressure and design data of the residual coal pillars. 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Accurate P-phase arrivals are critical for improving accuracy of source locations and MS parameters. In this study, a multi-step method (CNN-KA) combining convolutional neural network (CNN) combined, K-means and Akaike information criterion (AIC) is proposed. Firstly, CNN is applied to recognize mining-induced waveforms of rock fractures. Secondly, maximum overlapping discrete wavelet transform and multi-resolution analysis are integrated to denoise for acquired waveforms. Subsequently, a new picker was developed by introducing K-mean clustering to AIC. Finally, performance of the proposed CNN-KA was evaluated with open-access and in-field data. Combined with software development, the proposed method was applied in 12123 working face of Paner coal mine in Anhui Province, China. The results show that accuracy of CNN-KA in recognizing mining-induced rock fracturing events is 98.11%. The mean absolute error of CNN-KA is 0.0915s at 200Hz frequency, which is 86.65% lower than STA/LTA (short-term average to long-term average, one of the most commonly used in MS technology). The error of picking and positioning are 3.7ms and 10.89m respectively at 5000Hz frequency. MS source parameters based on CNN-KA was effectively used to interpret the abnormal dynamic response of the roof stratum in 12123 working face of Paner coal mine, which was confirmed by real-time mine pressure and design data of the residual coal pillars. The results can be further used for calculating precise MS source parameters and early warning of engineering geohazards.</abstract><pub>IEEE</pub><doi>10.1109/TGRS.2025.3528433</doi><tpages>1</tpages><orcidid>https://orcid.org/0000-0003-4455-9028</orcidid><orcidid>https://orcid.org/0000-0003-1987-7104</orcidid></addata></record>
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subjects Accuracy
Coal
Coal mine
Coal mining
Convolutional neural networks
Deep learning
Excavation
Face recognition
Geology
Microseismic monitoring
Mining-induced data
Monitoring
P-phase arrival
Rocks
Sensors
title CNN-KA: A Hybrid P-phase Picking Method for Microseismic Source Location in Deep Mine with Complex Geological Conditions
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