Joint elastic full waveform inversion of multi-component geophone and distributed acoustic sensing data
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Abstract
Joint full waveform inversion (FWI) of distributed acoustic sensing (DAS) and ocean-bottom node (OBN) data typically requires converting measured strain to particle velocity, introducing numerical noise and spectral distortion.
To eliminate this, we present an elastic multi-parameter FWI framework using a velocity-stress-strain (VSS) formulation that directly models pressure, particle velocity, and gauge-length-averaged DAS strain from a single forward simulation.
Data residuals are injected additively into a single backward simulation, making computational cost independent of the active sensor subsets.
We benchmark individual and combined datasets on cross-talk and elastic Marmousi models.
Our results show that joint inversion recovers elastic parameters more accurately than single deployments when the sensors offer complementary information.
Specifically, pairing two-component geophones with a deviated borehole DAS cable yields the most accurate parameter recovery and mitigates inter-parameter cross-talk by providing a distinct physical observable and complementary depth aperture.
We release our implementation as xFWI, an open-source, Devito-based Python package for scalable, multi-deployment inversions.