Abstract
This paper proposes a randomized subspace learning based anomaly detector (RSLAD) for hyperspectral imagery (HSI). Improved from robust principal component analysis, the RSLAD assumes that the background matrix is low-rank, and the anomaly matrix is sparse with a small portion of nonzero columns (i.e., column-wise). It also assumes the anomalies do not lie in the column subspace of the background and aims to find a randomized subspace of the background to detect the anomalies. First, random techniques including random sampling and random Hadamard projections are implemented to construct a coarse randomized columns subspace of the background with reduced computational cost. Second, anomaly columns are searched and removed from the coarse randomized column subspace by solving a series of least squares problems, resulting in a purified randomized column subspace. Third, the nonzero columns in the anomaly matrix are located by projecting all the pixels on the orthogonal subspace of the purified subspace, and the anomalies are finally detected based on the L2 norm of the columns in the anomaly matrix. The detection performance of RSLAD is compared with four state-of-the-art methods, including global Reed-Xiaoli (GRX), local RX (LRX), collaborative-representation based detector (CRD), and low-rank and sparse matrix decomposition base anomaly detector (LRaSMD). Experimental results show good detection performance of RSLAD with lower computational cost. Therefore, the proposed RSLAD offers an alternative option for hyperspectral anomaly detection.
Highlights
Hyperspectral imaging collects detailed spectral information of ground objects on the earth surface using hundreds of narrow and continuous bands [1,2]
4I.1n.pTuht:etHheSHI DSIabtaansedt mDaetsrcirxipYti=on{syi}iN=1 ∈ RM×N, the number of sampled pixels p, the projected dimension K, anTdhtehefirresstidduaatlatshertesishotlhdeεP. avia Center (PaviaC) dataset acquired by the reflective optics system iarme(c1sca)ouglrui((aCnabtt))oigeonngssOOprstrobbeucuttcoacatntivirnndaoettrmcthhiorneeeuagtrrpteeshrtedrohiujrn(eeacRcfnesotOdpedrdSoemmcmImSaatrit)atzuritioesrmxedinxYn.crYsΨToaoΦlhnbureygbm[yenr1nau2rfnars,m3odnu7mdobb]mose.pm4rIsa3toacH0fcmeoabtpodvalanei8nmrd6gs0asirtnindhnm(ep2thr).Po;eIajneivcntitiahitoeinCaselexdinnpat(eet3arr)is;mienteinnsot1,r1tt5hheewrdintihgIit1taa.l3lymnaunsmpdabhteiarassl o(f2)a sPmuarilflyerthiemcaogaersewceorleumunsesdubasspathceeYinΦpouftthdeabtaa,ckcgornotuaninding 108 × 120 pixels and 102 bands after reFmoroavllinpgixelloswdo signal-to-noise ratio (SNR) bands
The first dataset is the Pavia Center (PaviaC) dataset acquired by the reflective optics system imaging spectrometer (ROSIS) sensor [12,37]
Summary
Hyperspectral imaging collects detailed spectral information of ground objects on the earth surface using hundreds of narrow and continuous bands [1,2]. The RPCA based anomaly detectors assume that the background is low-rank and the anomalies are sparse in the image scene. The low-rank and sparse representation (LRASR) based detector regards that a background pixel can be approximately represented by a background dictionary and the anomalies are estimated from the residual sparse image [33]. In this paper, inspired by RPCA [38,39,40], we propose a randomized subspace learning based anomaly detector (RSLAD) for hyperspectral anomaly detection. (2) The idea behind RSLAD is more advanced than current sparsity based anomaly detectors It is to find a randomized subspace of the background and investigates the low-dimensionality of the background column subspace and the independence between anomalies.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
