An automatic microseismic or acoustic emission arrival identification scheme with deep recurrent neural networks

Summary The conventional arrival pick-up algorithms cannot avoid the manual modification of the parameters for the simultaneous identification of multiple events under different signal-to-noise ratios (SNRs). Therefore, in order to automatically obtain the arrivals of multiple events with high preci...

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Veröffentlicht in:Geophysical journal international 2018-02, Vol.212 (2), p.1389-1397
Hauptverfasser: Zheng, Jing, Lu, Jiren, Peng, Suping, Jiang, Tianqi
Format: Artikel
Sprache:eng
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Zusammenfassung:Summary The conventional arrival pick-up algorithms cannot avoid the manual modification of the parameters for the simultaneous identification of multiple events under different signal-to-noise ratios (SNRs). Therefore, in order to automatically obtain the arrivals of multiple events with high precision under different SNRs, in this study an algorithm was proposed which had the ability to pick up the arrival of microseismic or acoustic emission events based on deep recurrent neural networks. The arrival identification was performed using two important steps, which included a training phase and a testing phase. The training process was mathematically modelled by deep recurrent neural networks using Long Short-Term Memory architecture. During the testing phase, the learned weights were utilized to identify the arrivals through the microseismic/acoustic emission data sets. The data sets were obtained by rock physics experiments of the acoustic emission. In order to obtain the data sets under different SNRs, this study added random noise to the raw experiments’ data sets. The results showed that the outcome of the proposed method was able to attain an above 80 per cent hit-rate at SNR 0 dB, and an approximately 70 per cent hit-rate at SNR −5 dB, with an absolute error in 10 sampling points. These results indicated that the proposed method had high selection precision and robustness.
ISSN:0956-540X
1365-246X
DOI:10.1093/gji/ggx487