Physics-Consistent Data-driven Waveform Inversion with Adaptive Data Augmentation
This work addresses challenges in subsurface imaging for geophysical applications, representing an incremental improvement through hybrid methodology.
The authors tackled the ill-posedness and high computational cost of seismic full-waveform inversion by developing a hybrid approach combining physics-based models with data-driven methods, resulting in higher accuracy and greater generalization ability compared to purely physics-based or data-driven approaches.
Seismic full-waveform inversion (FWI) is a nonlinear computational imaging technique that can provide detailed estimates of subsurface geophysical properties. Solving the FWI problem can be challenging due to its ill-posedness and high computational cost. In this work, we develop a new hybrid computational approach to solve FWI that combines physics-based models with data-driven methodologies. In particular, we develop a data augmentation strategy that can not only improve the representativity of the training set but also incorporate important governing physics into the training process and therefore improve the inversion accuracy. To validate the performance, we apply our method to synthetic elastic seismic waveform data generated from a subsurface geologic model built on a carbon sequestration site at Kimberlina, California. We compare our physics-consistent data-driven inversion method to both purely physics-based and purely data-driven approaches and observe that our method yields higher accuracy and greater generalization ability.