Abstract
Hyperspectral images (HSIs) often contain pixels with mixed spectra, which makes it difficult to accurately separate the background signal from the anomaly target signal. To mitigate this problem, we present a method that applies spectral unmixing and structure sparse representation to accurately extract the pure background features and to establish a structured sparse representation model at a sub-pixel level by using the Archetypal Analysis (AA) scheme. Specifically, spectral unmixing with AA is used to unmix the spectral data to obtain representative background endmember signatures. Moreover the unmixing reconstruction error is utilized for the identification of the target. Structured sparse representation is also adopted for anomaly target detection by using the background endmember features from AA unmixing. Moreover, both the AA unmixing reconstruction error and the structured sparse representation reconstruction error are integrated together to enhance the anomaly target detection performance. The proposed method exploits background features at a sub-pixel level to improve the accuracy of anomaly target detection. Comparative experiments and analysis on public hyperspectral datasets show that the proposed algorithm potentially surpasses all the counterpart methods in anomaly target detection.
Highlights
Hyperspectral imaging technology has the ability to discriminate between different materials on the basis of their unique spectral signatures
With regard to the first issue encountered by using Minimum Volume Constrained Nonnegative Matrix Factorization (MV-Nonnegative Matrix Factorization (NMF)) unmixing method for anomaly detection (AD), the first objective of this study is to introduce the model of Archetypal Analysis (AA) [28]
By using the AA unmixing model, the unmixing reconstruction error can be used for AD
Summary
Hyperspectral imaging technology has the ability to discriminate between different materials on the basis of their unique spectral signatures. Each image represents a narrow wavelength range of the electromagnetic spectrum, known as a spectral band. These “images” are combined to form a three-dimensional hyperspectral data cube that contains rich spatial and spectral information. Due to such information, hyperspectral imaging has been widely used in practical applications [1,2], such as use for precision agriculture [1], identification of the germination status of tree seeds [2], distinguishing between healthy and non-healthy skin [3], target detection [4], etc.
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