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Main Authors: Torres-Quintero, Javier, Goyes-Peñafiel, Paul, Mantilla-Dulcey, Ana, Rodríguez-López, Luis, Sanabria-Gómez, José, Arguello, Henry
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2502.00887
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author Torres-Quintero, Javier
Goyes-Peñafiel, Paul
Mantilla-Dulcey, Ana
Rodríguez-López, Luis
Sanabria-Gómez, José
Arguello, Henry
author_facet Torres-Quintero, Javier
Goyes-Peñafiel, Paul
Mantilla-Dulcey, Ana
Rodríguez-López, Luis
Sanabria-Gómez, José
Arguello, Henry
contents Seismic data preconditioning is essential for subsurface interpretation. It enhances signal quality while attenuating noise, improving the accuracy of geophysical tasks that would otherwise be biased by noise. Although classical poststack seismic data enhancement methods can effectively reduce noise, they rely on predefined statistical distributions, which often fail to capture the complexity of seismic noise. On the other hand, deep learning methods offer an alternative but require large and diverse data sets. Typically, static databases are used for training, introducing domain bias, and limiting adaptability to new noise poststack patterns. This work proposes a novel two-process dynamic training method to overcome these limitations. Our method uses a dynamic database that continuously generates clean and noisy patches during training to guide the learning of a supervised enhancement network. This dynamic-guided learning workflow significantly improves generalization by introducing variability into the training data. In addition, we employ a domain adaptation via a neural style transfer strategy to address the potential challenge of encountering unknown noise domains caused by specific geological configurations. Experimental results demonstrate that our method outperforms state-of-the-art solutions on both synthetic and field data, within and outside the training domain, eliminating reliance on known statistical distributions and enhancing adaptability across diverse data sets of poststack data.
format Preprint
id arxiv_https___arxiv_org_abs_2502_00887
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Poststack Seismic Data Preconditioning via Dynamic Guided Learning
Torres-Quintero, Javier
Goyes-Peñafiel, Paul
Mantilla-Dulcey, Ana
Rodríguez-López, Luis
Sanabria-Gómez, José
Arguello, Henry
Geophysics
J.2
Seismic data preconditioning is essential for subsurface interpretation. It enhances signal quality while attenuating noise, improving the accuracy of geophysical tasks that would otherwise be biased by noise. Although classical poststack seismic data enhancement methods can effectively reduce noise, they rely on predefined statistical distributions, which often fail to capture the complexity of seismic noise. On the other hand, deep learning methods offer an alternative but require large and diverse data sets. Typically, static databases are used for training, introducing domain bias, and limiting adaptability to new noise poststack patterns. This work proposes a novel two-process dynamic training method to overcome these limitations. Our method uses a dynamic database that continuously generates clean and noisy patches during training to guide the learning of a supervised enhancement network. This dynamic-guided learning workflow significantly improves generalization by introducing variability into the training data. In addition, we employ a domain adaptation via a neural style transfer strategy to address the potential challenge of encountering unknown noise domains caused by specific geological configurations. Experimental results demonstrate that our method outperforms state-of-the-art solutions on both synthetic and field data, within and outside the training domain, eliminating reliance on known statistical distributions and enhancing adaptability across diverse data sets of poststack data.
title Poststack Seismic Data Preconditioning via Dynamic Guided Learning
topic Geophysics
J.2
url https://arxiv.org/abs/2502.00887