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http://dx.doi.org/10.3807/COPP.2020.4.3.210

Weighted Collaborative Representation and Sparse Difference-Based Hyperspectral Anomaly Detection  

Wang, Qianghui (Electronic and Optical Engineering Department, Army Engineering University)
Hua, Wenshen (Electronic and Optical Engineering Department, Army Engineering University)
Huang, Fuyu (Electronic and Optical Engineering Department, Army Engineering University)
Zhang, Yan (Electronic and Optical Engineering Department, Army Engineering University)
Yan, Yang (Unit 31681 of the People's Liberation Army)
Publication Information
Current Optics and Photonics / v.4, no.3, 2020 , pp. 210-220 More about this Journal
Abstract
Aiming at the problem that the Local Sparse Difference Index algorithm has low accuracy and low efficiency when detecting target anomalies in a hyperspectral image, this paper proposes a Weighted Collaborative Representation and Sparse Difference-Based Hyperspectral Anomaly Detection algorithm, to improve detection accuracy for a hyperspectral image. First, the band subspace is divided according to the band correlation coefficient, which avoids the situation in which there are multiple solutions of the sparse coefficient vector caused by too many bands. Then, the appropriate double-window model is selected, and the background dictionary constructed and weighted according to Euclidean distance, which reduces the influence of mixing anomalous components of the background on the solution of the sparse coefficient vector. Finally, the sparse coefficient vector is solved by the collaborative representation method, and the sparse difference index is calculated to complete the anomaly detection. To prove the effectiveness, the proposed algorithm is compared with the RX, LRX, and LSD algorithms in simulating and analyzing two AVIRIS hyperspectral images. The results show that the proposed algorithm has higher accuracy and a lower false-alarm rate, and yields better results.
Keywords
Spectroscopy; Hyperspectral images; Anomaly detection; Spectral information; Collaborative representation method;
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