2018
DOI: 10.3390/rs10010103
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Recursive Local Summation of RX Detection for Hyperspectral Image Using Sliding Windows

Abstract: Abstract:Anomaly detection has received considerable interest for hyperspectral data exploitation due to its high spectral resolution. Fast processing and good detection performance are practically significant in real world problems. Aiming at these requirements, this paper develops a recursive local summation RX anomaly detection approach by virtue of sliding windows. This paper develops a recursive local summation RX anomaly detection approach by virtue of sliding windows. A causal sample covariance/correlat… Show more

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Cited by 12 publications
(7 citation statements)
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“…One is the global RX (GRX), in which all pixels in the image are viewed as background and used to calculate background statistics. The other is the local RX (LRX) [20][21][22], in which a sliding fixed-size dual-window is employed to select those surrounding pixels as the background pixels of each tested pixel to calculate local background statistics. However, the multivariate Gaussian distribution is too simple to accurately characterize the complicated background of real-world hyperspectral scenes.…”
Section: Introductionmentioning
confidence: 99%
“…One is the global RX (GRX), in which all pixels in the image are viewed as background and used to calculate background statistics. The other is the local RX (LRX) [20][21][22], in which a sliding fixed-size dual-window is employed to select those surrounding pixels as the background pixels of each tested pixel to calculate local background statistics. However, the multivariate Gaussian distribution is too simple to accurately characterize the complicated background of real-world hyperspectral scenes.…”
Section: Introductionmentioning
confidence: 99%
“…It can collect a wide range of electromagnetic spectrum nearly from visible to long-wavelength infrared. These spectra are represented by hundreds of continuous bands that can meticulously describe the characteristics of different materials to recognize their subtle differences [3]. Therefore, 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].…”
Section: Introductionmentioning
confidence: 99%
“…Hyperspectral image (HSI) delivers rich spectral information [1] that usually covers a large spectral range almost from visible to mid-infrared. These spectra are divided into hundreds of approximately continuous and very narrow spectral bands which have a strong ability to precisely characterize different objects and accurately recognize the subtle differences between surface materials [2,3]. Benefiting from its high spectral resolution, hyperspectral image has been successfully used in many applications [4], such as target detection [5,6], image classification [7,8], band selection [9,10], and hyperspectral unmixing [11,12].…”
Section: Introductionmentioning
confidence: 99%