Abstract
A hyperspectral image usually covers a large scale of ground scene, which contains various materials with different spectral properties. When directly exploring the background information using all the image pixels, complex spectral interactions and inter-/intra-difference of different samples will significantly reduce the accuracy of background evaluation and further affect the detection performance. To address this problem, this paper proposes a novel hyperspectral anomaly detection method based on separability-aware sample cascade model. Through identifying separability of hyperspectral pixels, background samples are sifted out layer-by-layer according to their separable degrees from anomalies, which can ensure the accuracy and distinctiveness of background representation. First, as spatial structure is beneficial for recognizing target, a new spectral–spatial feature extraction technique is used in this work based on the PCA technique and edge-preserving filtering. Second, depending on different separability computed by sparse representation, samples are separated into different sets which can effectively and completely reflect various characteristics of background across all the cascade layers. Meanwhile, some potential abnormal targets are removed at each selection step to avoid their effects on subsequent layers. Finally, comprehensively taking different good properties of all the separability-aware layers into consideration, a simple multilayer anomaly detection strategy is adopted to obtain the final detection map. Extensive experimental results on five real-world hyperspectral images demonstrate our method’s superior performance. Compared with seven representative anomaly detection methods, our method improves the average detection accuracy with great advantages.
Highlights
A hyperspectral image is a data cube that simultaneously conveys rich spatial information and spectral information [1,2]
This paper proposes a novel hyperspectral anomaly detection based on separability-aware sample cascade, which tries to improve the description ability of background from the view of complex samples selection
Note that all the results of local RX (LRX) and sparse representation-based detector (SRD) on different window sizes are shown in Table 1, and their best results for each hyperspectral image are underlined
Summary
A hyperspectral image is a data cube that simultaneously conveys rich spatial information and spectral information [1,2]. These spectra are represented by hundreds of continuous bands that can meticulously describe the characteristics of different materials to recognize their subtle differences [3] Owing to this good discriminative property of hyperspectral image, it has been widely used in many remote sensing research fields [4,5], such as image denoising [6,7], hyperspectral unmixing [8,9], band selection [10,11], target detection [12,13], and image classification [14,15]. Due to its property of knowing nothing about the hyperspectral image scene, anomaly detection, as one special research problem of target detection, has attracted lots of attention in remote sensing field [16] It aims at detecting the abnormal pixel whose spectrum has significant deviation from that of the given reference background. Hyperspectral anomaly detection has played a crucial role in both military and civilian areas
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