Targets detecting in the ocean using the cross-polarized channels of fully polarimetric SAR data 被引量：3

Targets detecting in the ocean using the cross-polarized channels of fully polarimetric SAR data

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摘要 Azimuth ambiguities （ghost targets） discrimination is of great interest with the development of a synthet- ic aperture radar （SAR）. And the azimuth ambiguities are often mistaken as actual targets and cause false alarms. For actual targets, HV channel signals acquired by a fully polarimetric SAR are approximately equal to a VH channel in magnitude and phase, i.e., the reciprocity theorem applies, but shifted in phase about ±π for the first-order azimuth ambiguities. Exploiting this physical behavior, the real part of the product of the two cross-polarized channels, i.e. （SHVSVH）, hereafter called A12r, is employed as a new parameter for a target detection at sea. Compared with other parameters, the contrast of A12r image between a target and the surrounding sea surface will be obviously increased when A12r image is processed by mean filtering algo- rithm. Here, in order to detect target with constant false-alarm rates （CFARs）, an analytical expression for the probability density function （pdf） ofA12r is derived based on the complexWishart-distribution. Because a value of A12r is greater/less than 0 for real target/its azimuth ambiguities, the first-order azimuth ambiguities can be completely removed by this A12r-based CFAR technology. Experiments accomplished over C-band RADARSAT-2 fully polarimetric imageries confirm the validity. Azimuth ambiguities （ghost targets） discrimination is of great interest with the development of a synthet- ic aperture radar （SAR）. And the azimuth ambiguities are often mistaken as actual targets and cause false alarms. For actual targets, HV channel signals acquired by a fully polarimetric SAR are approximately equal to a VH channel in magnitude and phase, i.e., the reciprocity theorem applies, but shifted in phase about ±π for the first-order azimuth ambiguities. Exploiting this physical behavior, the real part of the product of the two cross-polarized channels, i.e. （SHVSVH）, hereafter called A12r, is employed as a new parameter for a target detection at sea. Compared with other parameters, the contrast of A12r image between a target and the surrounding sea surface will be obviously increased when A12r image is processed by mean filtering algo- rithm. Here, in order to detect target with constant false-alarm rates （CFARs）, an analytical expression for the probability density function （pdf） ofA12r is derived based on the complexWishart-distribution. Because a value of A12r is greater/less than 0 for real target/its azimuth ambiguities, the first-order azimuth ambiguities can be completely removed by this A12r-based CFAR technology. Experiments accomplished over C-band RADARSAT-2 fully polarimetric imageries confirm the validity.

作者 WANG Yunhua LIU Xiaoyan LI Huimin ZHANG Yanmin

机构地区 Ocean Remote Sensing Institute College of Information Science & Engineering The First Institude of Oceanography

出处《Acta Oceanologica Sinica》 SCIE CAS CSCD 2015年第1期85-93,共9页 海洋学报（英文版）

基金 The National Natural Science Foundation of China under contract Nos 41376179 and 41106153

关键词 azimuth ambiguities polarimetric SAR CFAR detection algorithm azimuth ambiguities, polarimetric SAR, CFAR detection algorithm

分类号 P714 [天文地球—海洋科学]

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参考文献15

1Chen Jiong, Chen Yiyun, Yang Jian. 2009. Ship detection using polar- ization cross-entropy. IEEE Geoscience and Remote Sensing Let- ters, 6(4): 723-727.
2Ferrara G E Migiiaccio M, Nunziata F, et al. 2011. Generalized-K-based observation of metallic objects at sea in full-resolution synthetic aperture radar (SAR) data: a multipolarization study. IEEE ]our- nal of Oceanic Engineering, 36(2): 195-204.
3Freeman A. 1993. The effects of noise on polarimetric SAR data. In Pro- ceedings of IGARSS 93. Better Understanding of Earth Environ- ment, International on Geoscience and Remote Sensing, Vol. 2. Tokyo, Japan: IEEE, 799--802.
4GieruU C H. 2004. Statistical analysis of multilook SAR interferograms for CFAR detection of ground moving targets. IEEE Transactions on Geoscience and Remote Sensing, 42(4): 691-701.
5Gradshteyn I S, Ryzhik I M. 2007. Tables of Integrals, Series and Prod- uct. 7th ed. London: Academic.
6Jiang Qingshan, Aitnouri E, Wang Shengrui. 2000. Automatic detection for ship target in SAR imagery using PNN model. Canadian Jour- nal of Remote Sensing, 26(4): 297-305.
7Kuttikkad S, Chellappa R. 1994. Non-Gaussian CFAR techniques for target detection in high resolution SAIl images. IEEE Interna- tional Conference in Image Processing, ICIP-94, Vol. 1, Austin, TX. 910-914.
8Lee J S, Hoppel KW, Mango S A, et al. 1994. Intensity and phase staffs-tics of multilook polarimetric and interferometric SAR imagery. IEEE Transactions on Geoscience and Remote Sensing, 32(5): 1017-1028.
9Lee J S, Miller A R, Hoppel KW. 1994. Statistics of phase difference and product magnitude of multilook processed Gaussian signals. Waves in Random Media, 4(3): 307-319.
10Liu Chen, Gierull C H. 2007. A new application for PolSAR imagery in the field of moving target indication/ship detection. IEEE Trans- actions on Geoscience and Remote Sensing, 45(11): 3426-3436.

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2郝程鹏,侯朝焕.一种K-分布杂波背景下的双参数恒虚警检测器[J].电子与信息学报,2007,29(3):756-759. 被引量：10
3石志广,周剑雄,付强.K分布海杂波参数估计方法研究[J].信号处理,2007,23(3):420-424. 被引量：18
4L. M. Novak, S. D. Halversen, G. J. Owirka, et al. Effects of polarization and Resolution on SAR ATR [ J ]. IEEE Transac- tions on Aerospace and Electronic Systems, 1997, 33 ( 1 ) :102 -115.
5B. Maurizio, G. Carmela. CFAR detection of extended objects in high-resolution SARimages [ J ]. IEEE Transactions on Ge- oscience and Remote Sensing, 2005, 43(4) : 833 -843.
6E. Magraner, N. Bertaux, P. Refregier. Detection in Gamma- distributed nonhomogeneous background [ J ]. IEEE Transac- tions on Aerospace and Electronic System, 2010, 46(3): 1127 - 1139.
7P. W. Vachon. Ship detection by the RADARSAT SAR: Vali- dation of detection model predictions[ J]. Canadian Journal of Remote Sensing, 1997, 23( 1 ) :48 -59.
8Gao Gui. A Parzen-window-kemel-based CFAR algorithm for ship detection in SAR images[ J]. IEEE Geoscience and Re- mote Sensing Letters, 2011, 8(3) : 557 -561.
9B. W. Silverman. Density estimation for statistics and data a- nalysis [M]. London: Chapman & Hall, 1986.
10胡文琳,王永良,王首勇.基于z^rlog(z)期望的K分布参数估计[J].电子与信息学报,2008,30(1):203-205. 被引量：16

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6吴永辉,计科峰,李禹,郁文贤.基于Wishart分布和MRF的多视全极化SAR图像分割[J].电子学报,2007,35(12):2302-2306. 被引量：13
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Targets detecting in the ocean using the cross-polarized channels of fully polarimetric SAR data 被引量：3

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