Abstract
This paper proposes an extension of the higher order singular value decomposition (HOSVD), namely the alternative unfolding HOSVD (AU-HOSVD), in order to exploit the correlated information in multidimensional data. We show that the properties of the AU-HOSVD are proven to be the same as those for HOSVD: the orthogonality and the low-rank (LR) decomposition. We next derive LR filters and LR detectors based on AU-HOSVD for multidimensional data composed of one LR structure contribution. Finally, we apply our new LR filters and LR detectors in polarimetric space-time adaptive processing (STAP). In STAP, it is well known that the response of the background is correlated in time and space and has a LR structure in space-time. Therefore, our approach based on AU-HOSVD seems to be appropriate when a dimension (like polarimetry in this paper) is added. Simulations based on signal-to-interferenceplus-noise ratio (SINR) losses, probability of detection (Pd), and probability of false alarm (Pfa) show the interest of our approach: LR filters and LR detectors which can be obtained only from AU-HOSVD outperform the vectorial approach and those obtained from a single HOSVD.
Highlights
In signal processing, more and more applications deal with multidimensional data, whereas most of the signal processing algorithms are derived based on oneor two-dimensional models
We show the interest of our new LR filters and LR detectors based on AU-higher order singular value decomposition (HOSVD) in a particular case of multidimensional space-time adaptive processing (STAP): polarimetric STAP [22]
Wlr(1/2/3), Wlr(1/2,3), and Wlr(1,3/2), which can only be obtained by AU-HOSVD, outperform Wlr(1,2,3) and the 2D STAP for a small number of secondary data
Summary
More and more applications deal with multidimensional data, whereas most of the signal processing algorithms are derived based on oneor two-dimensional models. The matrix U(Al) is given by the singular value decomposition of the Al-dimension unfolding, [KHA]1A/.l..=/AUL ∈(AlC) I1×(A..l.)×VIP(Ails)Hth. e core tensor. It has the same properties as the HOSVD core tensor. The main motivation for introducing the new AU-HOSVD is to extract the correlated information when processing the low-rank decomposition. This is the purpose of the following proposition. Discussion on choice of partition and complexity As mentioned previously, the total number of AU-HOSVD for a Pth-order tensor is equal to BP. In its adaptive version, denoted as A1...AL , the matrices U(0A1), . . . , U(0AL) are replaced by their estimates U (0A1), . . . , U (0AL)
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