Abstract
Random noise attenuation has always been an indispensable step in the seismic exploration workflow. The quality of the results directly affects the results of subsequent inversion and migration imaging. This paper proposes a cycle-GAN denoising framework based on the data augmentation strategy. We introduced residual learning into the cycle-GAN to improve the training efficiency of the network. We proposed a method for generating labeled datasets directly from unlabeled real noisy data. Then we significantly improve the diversity of the training samples through an augmentation strategy. Through RCGAN, we can realize intelligent seismic data denoising work, which dramatically reduces the manual selection and intervention of denoising parameters. Finally, numerical experiments prove that our method has a remarkably good random noise suppression ability and a minimally damaging effect on useful seismic signals. The experiment tests on synthetic and real data also show the effectiveness and superiority of the proposed method RCGAN compared to the state-of-the-art denoising methods.
Highlights
I N petroleum exploration, the precise processing of seismic data can directly affect subsequent inversion and migration imaging accuracy
This paper proposed a cycle-Generative Adversarial Networks (GANs) based on residual learning (RCGAN) and achieved noise suppression work for real and synthetic seismic data
The APF method and RCGAN will be significantly better at suppressing random noise than DnCNN
Summary
I N petroleum exploration, the precise processing of seismic data can directly affect subsequent inversion and migration imaging accuracy. Seismic data denoising is an indispensable step to improve the signal-to-noise ratio(SNR) of seismic data, and the result directly affects the quality of subsequent data processing. High SNR is essential for many seismic exploration techniques such as AVO analysis, seismic attribute analysis, and micro-seismic monitoring. The suppression of random noise is essential to improving the SNR. While acquiring significant waves, various noise interferences are inevitably recorded, reducing the SNR of seismic data. This will seriously affect the SNR and resolution of the seismic migration profile (especially the deep layers), which will cause significant difficulties in data interpretation
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