Integrating U-nets into a Multi-scale Waveform Inversion for Salt Body Building

TL;DR

This paper introduces a novel multi-scale waveform inversion method incorporating deep learning to accurately recover salt bodies from limited, low-frequency seismic data starting from poor initial models.

Contribution

It develops a multi-stage deep learning-enhanced FWI approach that effectively floods and unfloods salt bodies across frequency scales, improving salt imaging with limited data.

Findings

Successfully recovered salt bodies in synthetic models with limited data.

Applied method to real Gulf of Mexico data, achieving accurate salt imaging.

Demonstrated robustness with limited frequency and offset data.

Abstract

In salt provinces, full-waveform inversion (FWI) is most likely to fail when starting with a poor initial model that lacks the salt information. Conventionally, salt bodies are included in the FWI starting model by interpreting the salt boundaries from seismic images, which is time-consuming and prone to error. Studies show that FWI can improve the interpreted salt provided that the data are recorded using long offsets, and contain low frequencies, which are not always available. Thus, we develop an approach to invert for the salt body starting from a poor initial model, limited data offsets, and the absence of low frequencies. We leverage deep learning to apply multi-stage flooding and unflooding of the velocity model. Specifically, we apply a multi-scale FWI using three frequency bandwidths. We apply a network after each frequency scale. After the first two bandwidths, the networks are trained to flood the salt, while the network after the last frequency bandwidth is trained to unflood it. We verify the method on the synthetic BP 2004 salt model benchmark. We only use the synthetic data of short offsets up to 6 km and remove frequencies below 3 Hz. We also apply the method to real vintage data acquired in the Gulf of Mexico region. The real data lack frequencies below 6 Hz and the streamer length is only 4.8 km. With these limitations, we manage to recover the salt body and verify the result by using them to image the data and analyze the resulting angle gathers.