2014
DOI: 10.1007/s11075-014-9930-0
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A fast SVD for multilevel block Hankel matrices with minimal memory storage

Abstract: Motivated by the Cadzow filtering in seismic data processing, this paper presents a fast SVD method for multilevel block Hankel matrices. A seismic data presented as a multidimensional array is first transformed into a two dimensional multilevel block Hankel (MBH) matrix. Then the Lanczos process is applied to reduce the MBH matrix into a bidiagonal or tridiagonal matrix. Finally, the SVD of the reduced matrix is computed using the twisted factorization method. To achieve high efficiency, we propose a novel fa… Show more

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Cited by 22 publications
(11 citation statements)
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“…Table 3 provides a summary of experiments that contrast the computational costs of Algorithm 3, both with and without use of fast matrix-matrix multiplication, FBHMRSVD, and RSVD, and for direct calculation using the partial SVD. FBHMVM can also be realized using the 1DFFT [15], and these experiments are also reported. They demonstrate that using the 1DFFT generally increases the computational costs.…”
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confidence: 89%
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“…Table 3 provides a summary of experiments that contrast the computational costs of Algorithm 3, both with and without use of fast matrix-matrix multiplication, FBHMRSVD, and RSVD, and for direct calculation using the partial SVD. FBHMVM can also be realized using the 1DFFT [15], and these experiments are also reported. They demonstrate that using the 1DFFT generally increases the computational costs.…”
mentioning
confidence: 89%
“…In this paper, a fast block Hankel matrix randomized SVD (FBHMRSVD) algorithm that requires minimal storage is proposed. FBHMRSVD is based on fast block Hankel matrix-vector multiplications (FBHMVM) [27,15] and the use of a randomized SVD (RSVD) [12,11,25]. A fast non-convex low-rank matrix decomposition for potential field separation (FNCLRMD PFS) based on the FBHMRSVD is obtained.…”
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confidence: 99%
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“…The computational burden may cause an issue when say filtering in two spatial dimensions simultaneously, in which case bold-italicD is a block Hankel matrix of size N2×N2 if each spatial tie is in the order of N trace by N trace. In this case, by using Lanczos process and fast Hankel matrix‐vector multiplication (Trickett, 2003; Lu et al ., 2015), the computational complexity of estimating the entire singular values and the first L singular values are O(N4) and O(LN2), respectively. Thus, computing RT15 could be more efficient than RWZG20, though we note that the window size N is usually not too large in practice (such as 15 in T15) so that the events can be regarded as linear.…”
Section: Figurementioning
confidence: 99%
“…Firstly, high computational cost during SVD process is the biggest problem we encounter especially for 5D dataset [54], [55]. Since our target multi-level block Hankel/Toeplitz matrix or tensor array tends to be extremely large, the truncated SVD process consumes huge amounts of time.…”
Section: Introductionmentioning
confidence: 99%