THE USE OF DEEP LEARNING TO DETERMINE ARRIVAL TIME OF P AND S WAVES FOR GEOTHERMAL MICROSEISMIC DATA
The output of microseismic data processing depends on the quality of P and S wave picking, which is commonly peformed manually by geophysicist, but this process is time-consuming and prone to human subjectivity. New technologies such as deep learning can help reduce subjectivity and improve effic...
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id-itb.:862802024-09-17T11:47:53ZTHE USE OF DEEP LEARNING TO DETERMINE ARRIVAL TIME OF P AND S WAVES FOR GEOTHERMAL MICROSEISMIC DATA Haris Fahromi, Iqram Indonesia Final Project deep learning, geothermal, microseismic, PhaseNet, seismology INSTITUT TEKNOLOGI BANDUNG https://digilib.itb.ac.id/gdl/view/86280 The output of microseismic data processing depends on the quality of P and S wave picking, which is commonly peformed manually by geophysicist, but this process is time-consuming and prone to human subjectivity. New technologies such as deep learning can help reduce subjectivity and improve efficiency in microseismic data processing. The development of deep learning technology in seismology has shown an improvement in seismicity monitoring performance, especially for P and S wave arrival times picking. However, these deep learning models are trained using regional tectonic earthquake data that has different characteristics from microseismic in the geothermal field. The difference in earthquake characteristics will affect the accuracy and performance of the deep learning model. This final project research focuses on training the PhaseNet automatic picker model using microseismic data and evaluating its performance by comparing the predicted arrival time catalog with the manual catalog, and analyzing it using the concept of confusion matrix. The training results produced three automatic picker models, such as: Model 1 which was trained using only microseismic data, and Model 2 and Model 3 which were trained using transfer learning techniques from the pretrained INSTANCE model, with Model 3 adding freezing to the deepest architectural layer. The analysis results of the three models show an improvement in performance compared to the original PhaseNet model, this is shown by the F1 score of the P phase increasing from 0.62 to an average of 0.93, and the F1 score of the S phase from 0.62 to an average of 0.77. These results prove that the use of deep learning models specifically trained with microseismic data can improve their performance in determining the arrival time of P and S waves in geothermal microseismic data text |
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Indonesia |
| description |
The output of microseismic data processing depends on the quality of P and S wave
picking, which is commonly peformed manually by geophysicist, but this process is
time-consuming and prone to human subjectivity. New technologies such as deep
learning can help reduce subjectivity and improve efficiency in microseismic data
processing. The development of deep learning technology in seismology has shown
an improvement in seismicity monitoring performance, especially for P and S wave
arrival times picking. However, these deep learning models are trained using
regional tectonic earthquake data that has different characteristics from
microseismic in the geothermal field. The difference in earthquake characteristics
will affect the accuracy and performance of the deep learning model. This final
project research focuses on training the PhaseNet automatic picker model using
microseismic data and evaluating its performance by comparing the predicted
arrival time catalog with the manual catalog, and analyzing it using the concept of
confusion matrix. The training results produced three automatic picker models,
such as: Model 1 which was trained using only microseismic data, and Model 2
and Model 3 which were trained using transfer learning techniques from the pretrained INSTANCE model, with Model 3 adding freezing to the deepest
architectural layer. The analysis results of the three models show an improvement
in performance compared to the original PhaseNet model, this is shown by the F1
score of the P phase increasing from 0.62 to an average of 0.93, and the F1 score
of the S phase from 0.62 to an average of 0.77. These results prove that the use of
deep learning models specifically trained with microseismic data can improve their
performance in determining the arrival time of P and S waves in geothermal
microseismic data |
| format |
Final Project |
| author |
Haris Fahromi, Iqram |
| spellingShingle |
Haris Fahromi, Iqram THE USE OF DEEP LEARNING TO DETERMINE ARRIVAL TIME OF P AND S WAVES FOR GEOTHERMAL MICROSEISMIC DATA |
| author_facet |
Haris Fahromi, Iqram |
| author_sort |
Haris Fahromi, Iqram |
| title |
THE USE OF DEEP LEARNING TO DETERMINE ARRIVAL TIME OF P AND S WAVES FOR GEOTHERMAL MICROSEISMIC DATA |
| title_short |
THE USE OF DEEP LEARNING TO DETERMINE ARRIVAL TIME OF P AND S WAVES FOR GEOTHERMAL MICROSEISMIC DATA |
| title_full |
THE USE OF DEEP LEARNING TO DETERMINE ARRIVAL TIME OF P AND S WAVES FOR GEOTHERMAL MICROSEISMIC DATA |
| title_fullStr |
THE USE OF DEEP LEARNING TO DETERMINE ARRIVAL TIME OF P AND S WAVES FOR GEOTHERMAL MICROSEISMIC DATA |
| title_full_unstemmed |
THE USE OF DEEP LEARNING TO DETERMINE ARRIVAL TIME OF P AND S WAVES FOR GEOTHERMAL MICROSEISMIC DATA |
| title_sort |
use of deep learning to determine arrival time of p and s waves for geothermal microseismic data |
| url |
https://digilib.itb.ac.id/gdl/view/86280 |
| _version_ |
1822011001448431616 |