Owing to the large scale and dimensionality of a 3D seismic experiment, acquiring fully-sampled data according to the Nyquist criterion is an exceedingly arduous and costprohibitive task. In this paper, we develop tools to interpolate 5D seismic volumes with randomly missing sources or receivers using a relatively novel tensor format known as the Hierarchical Tucker (HT) format. By exploiting the underlying smooth structure of HT tensors, specifically its smooth manifold structure, we develop solvers which are fast, immediately parallelizable, and SVD-free, making these solvers amenable to large-scale problems where SVD-based projection methods are far too costly. We also build on intuition of multidimensional sampling from the perspective of matrix-completion and demonstrate the ability of our algorithms to recover frequency slices even amidst very high levels of source subsampling on a synthetic large-scale 3D North Sea dataset.
[1]
Daniel Kressner,et al.
Algorithm 941
,
2014
.
[2]
L. Demanet.
Curvelets, Wave Atoms, and Wave Equations
,
2006
.
[3]
Bart Vandereycken,et al.
The geometry of algorithms using hierarchical tensors
,
2013,
Linear Algebra and its Applications.
[4]
Nadia Kreimer,et al.
A tensor higher-order singular value decomposition for prestack seismic data noise reduction and interpolation
,
2012
.
[5]
Emmanuel J. Candès,et al.
Exact Matrix Completion via Convex Optimization
,
2008,
Found. Comput. Math..
[6]
Mauricio D. Sacchi,et al.
A Fast Rank Reduction Method For the Reconstruction of 5D Seismic Volumes
,
2011
.