MODEL OPTIMIZE FOR DEEP LEARNING ALGORITHM IN DETERMINE THE ARRIVAL TIME OF P AND S WAVES IN MICROSEISMIC DATA OF
In recent years, the amount of data generated by seismograms has been increasing, especially in geothermal areas. This poses a big challenge in seismic data processing, as the amount of data that must be analysed is not proportional to the human resources available to do it manually. Therefore, a...
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id-itb.:878802025-02-03T21:04:40ZMODEL OPTIMIZE FOR DEEP LEARNING ALGORITHM IN DETERMINE THE ARRIVAL TIME OF P AND S WAVES IN MICROSEISMIC DATA OF Rahadi Pangestu, Rayden Indonesia Final Project deep learning, microseismic, geothermal, phasenet INSTITUT TEKNOLOGI BANDUNG https://digilib.itb.ac.id/gdl/view/87880 In recent years, the amount of data generated by seismograms has been increasing, especially in geothermal areas. This poses a big challenge in seismic data processing, as the amount of data that must be analysed is not proportional to the human resources available to do it manually. Therefore, algorithms or tools are needed that are able to assist the data processing process efficiently and accurately. One algorithm that is widely used in seismic data analysis is PhaseNet, a deep learning algorithm designed to identify the arrival times of P and S waves in tectonic earthquakes. Although PhaseNet has proven effective in the context of tectonic earthquakes, its application to geothermal areas that have different seismic characteristics is often less than optimal in terms of prediction accuracy. This study aims to improve the performance of the PhaseNet algorithm in detecting wave arrival times in geothermal areas through training a model that is more suitable for the characteristics of microseismic data from geothermal fields. In this study, a comparison was made between three models: the PhaseNet model that has been retrained with microseismic data, the transfer learning model, and the initial PhaseNet model. Evaluation of the prediction results of each model was carried out by comparing them against manual catalogue picking data from the ‘RR’ geothermal field to obtain differences in prediction performance. Furthermore, an analysis using the confusion matrix concept was conducted to determine the best model based on evaluation metrics such as precision, recall, and F1 score. With this approach, it is hoped that this research can contribute to improving the accuracy of wave arrival time prediction in geothermal area seismic data, as well as reducing dependence on manual processes in seismic data analysis. text |
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In recent years, the amount of data generated by seismograms has been increasing, especially
in geothermal areas. This poses a big challenge in seismic data processing, as the amount of
data that must be analysed is not proportional to the human resources available to do it
manually. Therefore, algorithms or tools are needed that are able to assist the data processing
process efficiently and accurately. One algorithm that is widely used in seismic data analysis
is PhaseNet, a deep learning algorithm designed to identify the arrival times of P and S waves
in tectonic earthquakes. Although PhaseNet has proven effective in the context of tectonic
earthquakes, its application to geothermal areas that have different seismic characteristics is
often less than optimal in terms of prediction accuracy. This study aims to improve the
performance of the PhaseNet algorithm in detecting wave arrival times in geothermal areas
through training a model that is more suitable for the characteristics of microseismic data from
geothermal fields. In this study, a comparison was made between three models: the PhaseNet
model that has been retrained with microseismic data, the transfer learning model, and the
initial PhaseNet model. Evaluation of the prediction results of each model was carried out by
comparing them against manual catalogue picking data from the ‘RR’ geothermal field to
obtain differences in prediction performance. Furthermore, an analysis using the confusion
matrix concept was conducted to determine the best model based on evaluation metrics such
as precision, recall, and F1 score. With this approach, it is hoped that this research can
contribute to improving the accuracy of wave arrival time prediction in geothermal area
seismic data, as well as reducing dependence on manual processes in seismic data analysis. |
| format |
Final Project |
| author |
Rahadi Pangestu, Rayden |
| spellingShingle |
Rahadi Pangestu, Rayden MODEL OPTIMIZE FOR DEEP LEARNING ALGORITHM IN DETERMINE THE ARRIVAL TIME OF P AND S WAVES IN MICROSEISMIC DATA OF |
| author_facet |
Rahadi Pangestu, Rayden |
| author_sort |
Rahadi Pangestu, Rayden |
| title |
MODEL OPTIMIZE FOR DEEP LEARNING ALGORITHM IN DETERMINE THE ARRIVAL TIME OF P AND S WAVES IN MICROSEISMIC DATA OF |
| title_short |
MODEL OPTIMIZE FOR DEEP LEARNING ALGORITHM IN DETERMINE THE ARRIVAL TIME OF P AND S WAVES IN MICROSEISMIC DATA OF |
| title_full |
MODEL OPTIMIZE FOR DEEP LEARNING ALGORITHM IN DETERMINE THE ARRIVAL TIME OF P AND S WAVES IN MICROSEISMIC DATA OF |
| title_fullStr |
MODEL OPTIMIZE FOR DEEP LEARNING ALGORITHM IN DETERMINE THE ARRIVAL TIME OF P AND S WAVES IN MICROSEISMIC DATA OF |
| title_full_unstemmed |
MODEL OPTIMIZE FOR DEEP LEARNING ALGORITHM IN DETERMINE THE ARRIVAL TIME OF P AND S WAVES IN MICROSEISMIC DATA OF |
| title_sort |
model optimize for deep learning algorithm in determine the arrival time of p and s waves in microseismic data of |
| url |
https://digilib.itb.ac.id/gdl/view/87880 |
| _version_ |
1823658305349746688 |