A kernel weighted RX algorithm for anomaly detection in hyperspectral imagery

被引：0

作者：

Zhao C.-H. ^{[1
]}

Li J. ^{[2
]}

Mei F. ^{[1
]}

机构：

[1] College of Information and Communication Engineering, Harbin Engineering University

[2] College of Mechanical and Electrical, Beijing Institute of Technology

来源：

Hongwai Yu Haomibo Xuebao/Journal of Infrared and Millimeter Waves | 2010年 / 29卷 / 05期

关键词：

Anomaly detection; Hyperspectral imagery; Kernel functions; Weighted RX;

D O I：

10.3724/sp.j.1010.2010.00378

中图分类号：

学科分类号：

摘要：

A new mixed kernel function weighted RX algorithm for anomaly detection in hyperspectral imagery was proposed. First, each spectral pixel was mapped into a high-dimensional feature space by a nonlinear mapping function. Second the nonlinear information between different spectral bands of the hyperspectral imagery was exploited with the RX algorithm in the feature space. In order to optimize the covariance matrix, each pixel in the covariance matrix was weighted according to its centroid distance. In this way the weighted covariance matrix could represent the background distribution better. Finally, the dot product computation in the high-dimensional feature space were converted into the kernel computation in the low dimensional input space. The new spectral kernel function and the radial basis kernel function were composited according to the characteristic of hyperspectral data to improve the performance of the proposed algorithm. To validate the effectiveness of the proposed algorithm, experiments were conducted on real hyperspectral data. The results show that the proposed method can detect more anomaly targets than the RX algorithm in the feature space.

引用

页码：378 / 382

页数：4

共 12 条

[1] Scharf L.L., Friedlander B., Matched subspace detectors, IEEE Trans. on Signal Processing, 42, 8, pp. 2146-2157, (1994)
[2] Harsanyi J.C., Chang C.-I., Hyperspectral image classification and dimensionality reduction: An orthogonal subspace projection, IEEE Trans. on Geoscience and Remote Sensing, 32, 4, pp. 779-785, (1994)
[3] Shaw G., Mankolakis D., Signal processing for hyperspectral image exploitation, IEEE Signal Processing Magazine, 19, 1, pp. 12-16, (2002)
[4] He L., Pan Q., Di W., Multicategory targets detection of hyperspectral imagery based on adaptive structured background and shape-feature subspace, J. Infrared Millim. Waves, 26, 5, pp. 353-358, (2007)
[5] Zhang B., Chen Z.-C., Zheng L.-F., Et al., Object detection based on feature extraction from hyperspectralimagery and convex cone projection transform, J. Infrared Millim. Waves, 23, 6, pp. 441-445, (2004)
[6] Li Z.-Y., Kuang G.-Y., Yu W.-X., Et al., Algorithm on small target detection base on principal component of hyperspectral imagery, J. Infrared Millim. Waves, 23, 4, pp. 286-290, (2004)
[7] Gu Y.-F., Liu Y., Jia Y.-H., Et al., Anomaly detection algorithm of hyperspectral images based on spectral analyses, J. Infrared Millim. Waves, 25, 6, pp. 473-477, (2006)
[8] Reed I.S., Yu X., Adaptive Multiple-band CFAR Detection of an optical pattern with unknown spectral distribution, IEEE Trans. Acoust., Speech Singal Process, 38, 10, pp. 1760-1770, (1990)
[9] Chang C.-I., Chiang S.-S., Anomaly detection and classification for hyperspectral imagery, IEEE Trans. on Geoscience and Remote Sensing, 40, 6, pp. 1314-1325, (2002)
[10] Chang C.-I., Ren H., Chiang S.-S., Real-time processing algorithms for target detection and classification in hyperspectral imagery, IEEE Trans. on Geoscience and Remote Sensing, 39, 4, pp. 760-768, (2001)

← 1 2 →