StorSeismic: A New Paradigm in Deep Learning for Seismic Processing

Machine learned tasks on seismic data are often trained sequentially and separately, even though they utilize the same features (i.e., geometrical) of the data. We present StorSeismic as a dataset-centric framework for seismic data processing, which consists of neural network (NN) pretraining and fine-tuning procedures. We, specifically, utilize a NN as a preprocessing tool to extract and store seismic data features of a particular dataset for any downstream tasks. After pretraining, the resulting model can be utilized later, through a fine-tuning procedure, to perform different tasks using limited additional training. Used often in natural language processing (NLP) and lately in vision tasks, bidirectional encoder representations from transformer (BERT), a form of a transformer model, provides an optimal platform for this framework. The attention mechanism of BERT, applied here on a sequence of traces within the shot gather, is able to capture and store key geometrical features of the seismic data. We pretrain StorSeismic on field data, along with synthetically generated ones, in the self-supervised step. Then, we use the labeled synthetic data to fine-tune the pretrained network in a supervised fashion to perform various seismic processing tasks, such as denoising, velocity estimation, first arrival picking, and normal moveout (NMO). Finally, the fine-tuned model is used to obtain satisfactory inference results on the field data.

Automated summary

This paper presents a dataset-centric framework called StorSeismic for seismic data processing, which utilizes a neural network (NN) for preprocessing to extract and store geometrical features of the data. By pretraining and fine-tuning, this framework can be used for various seismic processing tasks such as denoising and velocity estimation.