Velocity estimation via registration-guided least-squares inversion

TL;DR

This paper presents RGLS, a novel velocity estimation method that uses registration-guided least-squares inversion with multiscale warpings, effectively avoiding cycle-skipping and improving convergence in seismic model updates.

Contribution

Introducing a registration-based iterative inversion scheme that employs piecewise-polynomial warpings and multiscale frequency sweeps for improved velocity estimation.

Findings

RGLS converges to correct models where traditional methods fail.

The method effectively handles cycle-skipping issues.

Successful application in transmission seismic scenarios.

Abstract

This paper introduces an iterative scheme for acoustic model inversion where the notion of proximity of two traces is not the usual least-squares distance, but instead involves registration as in image processing. Observed data are matched to predicted waveforms via piecewise-polynomial warpings, obtained by solving a nonconvex optimization problem in a multiscale fashion from low to high frequencies. This multiscale process requires defining low-frequency augmented signals in order to seed the frequency sweep at zero frequency. Custom adjoint sources are then defined from the warped waveforms. The proposed velocity updates are obtained as the migration of these adjoint sources, and cannot be interpreted as the negative gradient of any given objective function. The new method, referred to as RGLS, is successfully applied to a few scenarios of model velocity estimation in the transmission setting. We show that the new method can converge to the correct model in situations where conventional least-squares inversion suffers from cycle-skipping and converges to a spurious model.