基于最小熵的多通道SAR系统相位误差估计与补偿

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基于最小熵的多通道SAR系统相位误差估计与补偿

胡建民^1,2, 王岩飞¹, 李和平¹

1. 中国科学院电子学研究所, 北京 100190;
2. 中国科学院研究生院, 北京 100039

收稿日期:2011-11-09 修回日期:2012-02-14 出版日期:2012-10-25 发布日期:2012-10-25
通讯作者: 王岩飞 E-mail:yfwang@mail.ie.ac.cn
基金资助:
中国科学院知识创新项目(KGCX2-SW-414)

Phase Error Estimation and Compensation for Multi-channel SAR Systems Based on Entropy Minimization

HU Jianmin^1,2, WANG Yanfei¹, LI Heping¹

1. Institute of Electronics, Chinese Academy of Sciences, Beijing 100190, China;
2. Graduate University of Chinese Academy of Sciences, Beijing 100039, China

Received:2011-11-09 Revised:2012-02-14 Online:2012-10-25 Published:2012-10-25
Supported by:
Knowledge Innovation Program of the Chinese Academy of Sciences (KGCX2-SW-414)

摘要/Abstract

摘要： 采用多通道合成的方法来增加信号带宽,是提高合成孔径雷达(SAR)系统距离分辨率的一种有效技术手段。针对多通道间相位失配的问题,建立了通道相位误差的频域多项式模型,提出了一种基于最小熵的通道相位误差估计与补偿方法。以距离向压缩脉冲图像的信息熵作为目标函数,误差多项式系数为估计变量,基于最小熵准则建立了相位误差的最优化估计模型。该方法能有效弥补内定标或外定标方法的不足,且不依赖于成像场景的地物类型,只需抽取少量回波数据作为误差估计的样本,具有耗费存储空间少、收敛速度快、不损失信噪比的优点。对不同场景的八通道实测数据进行了处理,实验结果验证了本文方法的有效性和稳健性。

关键词: 多通道SAR系统, 相位误差, 最小熵, 估计, 补偿

Abstract: To improve the range resolution of a synthetic aperture radar (SAR) system, one of the effective technological approaches is to increase signal bandwidths via multi-channel synthesis. In view of the issue of channel phase mismatch among multi-channels, a method based on the principle of entropy minimization is proposed to estimate and compensate for channel phase error, which is modeled as a polynomial in the frequency domain. By adopting the image information entropy of a range compressed pulse as the objective function and taking the polynomial coefficients as the estimated variables, an optimal estimation model for channel phase errors is established based on the principle of entropy minimization. Characterized by independence from the surface feature of the imaging scene, this method effectively makes up for the insufficiency of internal or external calibration; meanwhile, it just requires a small amount of raw data as the sample for error estimation, which results in the advantage of no loss of SNR, few storage consumption and fast convergence speed. The validity and robustness of the method are demonstrated by the experimental results of eight-channel raw data processing from different scenes.

Key words: multi-channel SAR system, phase error, entropy minimization, estimation, compensation

中图分类号:

V243.2
TN958

胡建民, 王岩飞, 李和平. 基于最小熵的多通道SAR系统相位误差估计与补偿[J]. 航空学报, 2012, 33(10): 1893-1904.

HU Jianmin, WANG Yanfei, LI Heping. Phase Error Estimation and Compensation for Multi-channel SAR Systems Based on Entropy Minimization[J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2012, 33(10): 1893-1904.

参考文献

[1] Wilden H, Brenner A R. The SAR/GMTI airborne radar PAMIR: technology and performance. IEEE Microwave Synposium. Anaheim C.A.: IEEE Microwave Theory and Techniques Society, 2010: 534-537.
[2] Brenner A R, Roessing L, Berens P. Potential of very high resolution SAR interferometry for urban building analysis. EUSAR, 2010: 1010-1013.
[3] Ruault du Plessis O, Nouvel J F, Baque R, et al. ONERA SAR facilities. IEEE Radar Conference, 2010: 667-672.
[4] Brenner A R. Proof of concept for airborne SAR imaging with 5 cm resolution in X-band. EUSAR, 2010: 615-618.
[5] Wilkinson A J, Lord R T, Inggs M R. Stepped-frequency processing by reconstruction of target reflectivity spectrum. IEEE Proceedings of Geoscience Remote Sensing Symposium, 1998: 101-104.
[6] Deng Y, Zheng H, Wang R, et al. Internal calibration for stepped-frequency chirp SAR imaging. IEEE Geoscience and Remote Sensing Letters, 2011, 8(6): 1105-1109.
[7] Freeman A. SAR calibration: an overview. IEEE Transactions on Geoscience and Remote Sensing, 1992, 30(6): 1107-1121.
[8] Zhang M, Liu C, Wang Y F. Channel error correction for ultra-high resolution airborne SAR system with synthetic bandwidth. Journal of Electronics and Information Technology, 2011, 33(12): 2813-2818. (in Chinese) 张梅, 刘畅, 王岩飞. 频带合成超高分辨率机载SAR系统的相位误差校正. 电子与信息学报, 2011, 33(12): 2813-2818.
[9] Carrara W G, Goodman R S, Majewski R M. Spotlight synthetic aperture radar: signal processing algorithms. Boston M.A.: Artech House, 1995: 203-222.
[10] Li X, Liu G S, Ni J L. Autofocusing of ISAR images based on entropy minimization. IEEE Transactions on Aerospace and Electronic Systems, 1999, 35(4): 1240- 1252.
[11] Qiu X H, Chen H. Entropy function optimization for radar imaging. Journal of Southeast University (English Edition), 2009, 25(4): 427-430.
[12] Kragh T J, Alaa Kharbouch A. Monotonic iterative algorithm for minimum-entropy autofocus. IEEE International Conference on Image Processing, 2006: 645-648.
[13] Zhu D Y, Wang L, Yu Y S, et al. Robust ISAR range alignment via minimizing the entropy of the average range profile. IEEE Geoscience and Remote Sensing Letters, 2009, 6(2): 204-208.
[14] Kolman J. Image reconstruction and restoration using constrained optimization algorithms. West Lafayette: Purdue University, 1996.
[15] Luenberger D G, Ye Y. Linear and nonlinear programming. 3rd ed. New York: Springer, 2008: 285-312.
[16] Raney R K, Runge H, Bamler R, et al. Precision SAR processing using chirp scaling. IEEE Transactions on Geoscience and Remote Sensing, 1994, 32(4): 786-799.
[17] Formaro G. Trajectory deviations in airborne SAR: analysis and compensation. IEEE Transactions on Aerospace and Electronic Systems, 1999, 35(3): 998-1003.
[18] Wahl D E, Eichel P H, Ghiglia D C, et al. Phase gradient autofocus-a robust tool for high resolution SAR phase correction. IEEE Transactions on Aerospace and Electronic Systems, 1994, 30(3): 827-834.

E-mail：hkxb@buaa.edu.cn

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主管单位：中国科学技术协会主办单位：中国航空学会北京航空航天大学

基于最小熵的多通道SAR系统相位误差估计与补偿

Phase Error Estimation and Compensation for Multi-channel SAR Systems Based on Entropy Minimization

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