Abstract
Anomaly target detection has been a hotspot of the hyperspectral imagery (HSI) processing in recent decades. One of the key research points in the HSI anomaly detection is the accurate descriptions of the background and anomaly targets. Considering this point, we propose a novel anomaly target detector in this article. Improving upon the low-rank and sparse matrix decomposition (LRaSMD) approach, the proposed method assumes that the low-rank component can be described as the parts-based representation. Parts refer to the various ground objects in HSI. A new update rule of the low-rank component and sparse component is proposed. The proposed approach can be divided into three main steps: first, further refining the low-rank component in the LRaSMD model as the parts-based representation. Then, the HSI is decomposed as three parts: the product of the basis matrix and coefficient matrix, sparse matrix, and noise. Second, the basis vectors matrix, coefficient matrix, and sparse matrix are solved by the new update rules. Third, since the anomaly targets exist in the sparse matrix, the sparse matrix is thus employed to detect the anomaly targets. The experiments implemented for five data sets demonstrate that the proposed algorithm achieved a better performance than the traditional algorithms.
Highlights
H YPERSPECTRAL imagery (HSI) has a high spectral resolution
We proposed a novel anomaly target detection algorithm that improved the original low-rank and sparse matrix decomposition (LRaSMD) algorithms to obtain a more accurate decomposition of hyperspectral imagery (HSI)
Based on the above-mentioned description of HSI, the proposed method divides the HSI decomposition optimization problem into three subproblems to compute the basis vector matrix, coefficient matrix, and sparse matrix, respectively. In both the original and improved LRaSMD, the accuracy of the sparse component was closely related to the accuracy of the low-rank component
Summary
H YPERSPECTRAL imagery (HSI) has a high spectral resolution. it contains abundant and detailedManuscript received December 10, 2019; revised February 23, 2020 and April 2, 2020; accepted May 3, 2020. H YPERSPECTRAL imagery (HSI) has a high spectral resolution. This advantage greatly improves the capabilities in distinguishing the ground objects, even for the minor differences between different objects [4]–[6]. The target detection and classification using HSI can be more effective than using multispectral imagery. The former application aims at extracting the objects of interest from a specific scene. The anomaly detectors use the characteristics of the anomaly target instead of prior target knowledge to implement the detection processing
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