一种基于多特征融合的新型光谱相似性测度

doi:10.3964/j.issn.1000-0593(2011)08-2166-05

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摘要：光谱相似性测度是高光谱遥感影像定量化分析和精细地物直接识别的基础，光谱特征的选择和刻画方式是光谱相似性测度的关键。研究表明，利用光谱的单一特征无法全面反应地物光谱间的相似性，光谱识别时需要综合考虑光谱的多种特征。本文在几何距离、相关系数和相对熵的基础上提出了一种结合多种光谱特征的新型光谱相似性测度，即光谱泛相似测度(spectral pan-similarity measure, SPM)。在进行光谱相似性分析时，SPM综合考虑光谱矢量大小、光谱曲线形状和光谱信息量三种光谱特征信息。基于美国地质调查局矿物光谱库和机载OMIS高光谱遥感影像进行试验，结果表明相对只考虑一种或两种特征的光谱相似性测度，SPM具有更强的光谱判别能力和更小的光谱识别不确定性。

关键词：高光谱遥感;光谱相似性测度;光谱泛相似测度;特征融合;光谱信息量

Abstract：Spectral characterization and feature selection is the key to spectral similarity measure which is the basis of both quantitative analysis and accurate object identification for hyperspectral remote sensing. However, spectral similarity measures using only one spectral feature are usually ambiguous in their distinction of similarity. Multiple spectral features integration is needed for objective spectral discrimination. We present a new spectral similarity measure, Spectral Pan-similarity Measure (SPM), based on geometric distance, correlation coefficient and relative entropy. Spectral Pan-similarity Measure objectively quantifies differences between spectra in three spectral features, the vector magnitude, spectral curve shape and spectral information content. The performance of different spectral similarity measures is compared using USGS Mineral Spectral Library and real (i.e., Operational Modular Imaging Spectrometer, OMIS) hyperspectral image. The experimental results demonstrate that the new spectral similarity measure is more effective than the spectral similarity measure taking into account only one or two features both in spectral discriminatory power and spectral identification uncertainty.

Key words：Hyperspectral remote sensing;Spectral similarity measure;Spectral pan-similarity measure (SPM);Features fusion;Spectral information content

收稿日期: 2010-10-11 修订日期: 2011-04-11

中图分类号:

TP753

通讯作者: 孔祥兵 E-mail: kongxb_whu@foxmail.com，kong.xb@hotmail.com

引用本文:

孔祥兵¹，舒宁¹，陶建斌²，龚 ¹. 一种基于多特征融合的新型光谱相似性测度[J]. 光谱学与光谱分析, 2011, 31(08): 2166-2170.
KONG Xiang-bing¹, SHU Ning¹, TAO Jian-bin², GONG Yan¹ . A New Spectral Similarity Measure Based on Multiple Features Integration . SPECTROSCOPY AND SPECTRAL ANALYSIS, 2011, 31(08): 2166-2170.

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[1] TONG Qing-xi, ZHANG Bing, ZHENG Lan-fen(童庆禧, 张兵, 郑兰芬). Hyperspectral Remote Sensing: Principle, Technology and Application(高光谱遥感——原理、技术与应用). Beijing: Higher Education Press(北京: 高等教育出版社), 2006. 40.
[2] DU Pei-jun, TANG Hong, FANG Tao(杜培军, 唐宏, 方涛). Geomatics and Information Science of Wuhan University(武汉大学学报·信息科学版), 2006, (2): 112.
[3] Chang C I, Chakravarty S, Chen H M, et al. Pattern Recognition, 2009, 42(3): 395.
[4] Keshava N. IEEE Transactions on Geoscience and Remote Sensing, 2004, 42(7): 1552.
[5] Kruse F A, Lefkoff A B, Boardman J W, et al. Remote Sensing Environment, 1993, 44(2-3): 145.
[6] Sohn Youngsinn, Rebello N Sanjay. Photogrammetric Engineering and Remote Sensing, 2002, 68(12): 1271.
[7] Vander Meer F, Bakker W. Int. J. Remote Sensing, 1997, 18(5): 1197.
[8] Chang C I. IEEE Transactions on Information Theory, 2000, 46(5): 1927.
[9] Chang C I. Hyperspectral Imaging: Techniques for Spectral Detection and Classification. Dordrecht：Kluwer Academic Publishers, 2003. 15.
[10] Van der Meer F. International Journal of Applied Earth Observation and Geoinformation，2006, 8(1): 3.
[11] Sweet J N. IEEE Workshop on Advances in Techniques for Analysis of Remotely Sensed Data, 2003，27-28: 92.
[12] FANG Sheng-hui, GONG Hao(方圣辉, 龚浩). Geomatics and Information Science of Wuhan University(武汉大学学报·信息科学版), 2006, 31(12): 1044.
[13] Du Y, Chang C I, Ren H. Optical Engineering, 2004, 43(8): 1777.
[14] Granahan J C, Sweet J N. IEEE 2001 International Geoscience and Remote Sensing Symposium, 2001，(5): 2022.
[15] Duda R O, Hart P E，Stork D G. Pattern Classification(2nd ed.). New York: John Wiley and Sons, 2001, (Chapter 4): 31.
[16] Clark R N, Swayze G A, Gallagher A J, et al. The US Geological Survey, Digital Spectral Library: Version 1: 0.2 to 3. 0 microns, US Geological Survey Open File Report 93-592, 1993: 1340.