Beating level-set methods for 3D seismic data interpolation: a primal-dual alternating approach
Abstract
Acquisition cost is a crucial bottleneck for seismic workflows, and low-rank formulations for data interpolation allow practitioners to `fill in' data volumes from critically subsampled data acquired in the field. Tremendous size of seismic data volumes required for seismic processing remains a major challenge for these techniques. We propose a new approach to solve residual constrained formulations for interpolation. We represent the data volume using matrix factors, and build a block-coordinate algorithm with constrained convex subproblems that are solved with a primal-dual splitting scheme. The new approach is competitive with state of the art level-set algorithms that interchange the role of objectives with constraints. We use the new algorithm to successfully interpolate a large scale 5D seismic data volume, generated from the geologically complex synthetic 3D Compass velocity model, where 80% of the data has been removed.
Cite
@article{arxiv.1607.02624,
title = {Beating level-set methods for 3D seismic data interpolation: a primal-dual alternating approach},
author = {Rajiv Kumar and Oscar López and Damek Davis and Aleksandr Y. Aravkin and Felix J. Herrmann},
journal= {arXiv preprint arXiv:1607.02624},
year = {2025}
}
Comments
16 pages, 7 figures