An approach to wide-field imaging of linear rail ground-based SAR in high squint multi-angle mode 被引量：2

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摘要 Ground-based synthetic aperture radar(GB-SAR) has been successfully applied to the ground deformation monitoring.However, due to the short length of the GB-SAR platform, the scope of observation is largely limited. The practical applications drive us to make improvements on the conventional linear rail GB-SAR system in order to achieve larger field imaging. First, a turntable is utilized to support the rotational movement of the radar.Next, a series of high-squint scanning is performed with multiple squint angles. Further, the high squint modulation phase of the echo data is eliminated. Then, a new multi-angle imaging method is performed in the wave number domain to expand the field of view. Simulation and real experiments verify the effectiveness of this method.

作者 ZHANG Yuan ZHANG Qiming WANG Yanping LIN Yun LI Yang BAI Zechao LI Fang

机构地区 School of Information Science and Technology Quanzhou Institute of Equipment Manufacturing

出处《Journal of Systems Engineering and Electronics》 SCIE EI CSCD 2020年第4期722-733,共12页 系统工程与电子技术（英文版）

基金 supported by the National Natural Science Foundation of China(61801007) the Beijing Natural Science Foundation(4194075)。

关键词 ground-based synthetic aperture radar(GB-SAR) high squint multi-angle

分类号 TN957.52 [电子电信—信号与信息处理]

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参考文献2

1Tao Zeng,Cong Mao,Cheng Hu,Mao Zhu,Weiming Tian,Jingjing Ren.Grating lobes suppression method for stepped frequency GB-SAR system[J].Journal of Systems Engineering and Electronics,2014,25(6):987-995. 被引量：3
2HAN KuoYe,WANG YanPing,CHANG XiangKe,TAN WeiXian,HONG Wen.Generalized pseudopolar format algorithm for radar imaging with highly suboptimal aperture length[J].Science China(Information Sciences),2015,58(4):59-73. 被引量：1

二级参考文献31

1G. Luzi. Ground based SAR interferometer: a novel tool for geoscience. http://www.intechopen.com/books/geoscience-and-remote-sensing-new-achievements/ground-based-sar-interferometry-a-novel-tool-for-geoscience. 2010. 被引量：1
2D. Leva, G. Nico. D. Tarchi. Temporal analysis of a landslide by means of a ground-based SAR interferometer. IEEE Trans.on Geoscience Remote Sensing, 2003, 41(4): 745-752. 被引量：1
3R. F. Hanssen. Radar Interferometer: data interpretation and error analysis. The Nethelands: Kluwer, 2001. 被引量：1
4L. Pipia, X. Fabregas. Atmosperic artifact compensation in ground-based DInSAR application. IEEE Trans, on Geoscience Remote Sensing, 2008, 5(1): 88-92. 被引量：1
5G. Luzi, M. Pieraccini. Ground-based radar interferometry for landslides monitoring: atmospheric and instrumental decorrelation sources on experimental data. IEEE Trans, on Geoscience Remote Sensing, 2004, 42(11): 2454-2466. 被引量：1
6V. Singhroy. Landslide hazards: CEOS, the use of earth observing satellites for hazard support: assessments and scenarios, http://www.inpe.br/crs/geodesastres/conteudo/livros/ CEOS-The.use-of-earth.observing_satellites-for_hazard_sup-port.pdf, 2002. 被引量：1
7V. Singhroy, K. Molch. Characterizing and monitoring rock-slides from SAR techniques. Advances in Space Research,2004, 33(3): 290-295. 被引量：1
8P. Canuti, N. Casagli. Landslide activity as a geoindicator in Italy: significance and new perspectives from remote sensing. Environmental Geology, 2004, 45(7): 907-919. 被引量：1
9A. Ferretti, C. Prati. Permanent scatterers in SAR interferometer. IEEE Trans, on Geoscience Remote Sensing, 2001, 39(1): 8-20. 被引量：1
10M. Pieraccini, N. Casagli. Landslide monitoring by ground-based radar interferometer: a field test in Valdamo (Italy). International Journal of Remote Sensing, 2003, 24(6): 1385 — 1391. 被引量：1

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1李杨,张宝林,李华,李松玲,孙晓峰,万成安.宇航电子产品汽相清洗技术研究[J].真空科学与技术学报,2019,39(4):310-315. 被引量：1
2李沐阳,胡程,王锐,李卫东,姜琦,李云龙,钱李昌,王江涛.高分辨全极化昆虫雷达极化校准与昆虫体轴方向估计[J].雷达学报（中英文）,2023,12(2):425-440. 被引量：1

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1张临杰,张杰,张晰,郎海涛.任务分配均衡的双参数CFAR舰船检测并行算法[J].遥感学报,2016,20(2):344-351. 被引量：8
2林赟,宋扬,王彦平,李洋.旋转扫描地基SAR大视场快速成像算法[J].信号处理,2019,35(3):499-506. 被引量：6
3杨龙,苏娟,李响.基于深度卷积神经网络的SAR舰船目标检测[J].系统工程与电子技术,2019,41(9):1990-1997. 被引量：21
4邱洪彬,王雪梅,许哲,张钧,宿常鹏.基于二维能量检测的舰船SAR图像阈值分割[J].系统工程与电子技术,2019,41(12):2747-2753. 被引量：4
5杜兰,王兆成,王燕,魏迪,李璐.复杂场景下单通道SAR目标检测及鉴别研究进展综述[J].雷达学报（中英文）,2020,9(1):34-54. 被引量：37
6张劲松,吴军,王星杰.地基合成孔径雷达在矿区边坡监测预警应用研究[J].工程勘察,2021,49(12):59-62. 被引量：16
7朱振宇,周乃恩,贺少帅.Sentinel-1A的近海固定设施和动态船只识别[J].遥感信息,2022,37(3):77-86. 被引量：1

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1崔兴超,李郝亮,付耀文,陈思伟,粟毅.空间目标散射结构极化旋转域辨识[J].电子与信息学报,2023,45(6):2105-2114. 被引量：1
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3孟智超,张磊,卢景月,李军.随机样本选择的合成孔径雷达距离空变相位梯度自聚焦算法[J].系统工程与电子技术,2023,45(12):3828-3835.

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6LingGao Kong,AiBing Zhang,Zhen Tian,XiangZhi Zheng,WenJing Wang,Bin Liu,Peter Wurz,Daniele Piazza,Adrian Etter,Bin Su,YaYa An,JianJing Ding,WenYa Li,Yong Liu,Lei Li,YiRen Li,Xu Tan,YueQiang Sun.Mars Ion and Neutral Particle Analyzer (MINPA) for Chinese Mars Exploration Mission (Tianwen-1): Design and ground calibration[J].Earth and Planetary Physics,2020,4(4):333-344. 被引量：7
7WANG Yong,RONG JiaJia,ZHANG QingXiang,HAN Tao.FMCW-InISAR imaging for high-speed target based on bistatic configuration[J].Science China(Technological Sciences),2020,63(8):1452-1469. 被引量：1
8Linan YUAN,Jingjuan LIAO.Exploring the influence of various factors on microwave radiation image simulation for Moon-based Earth observation[J].Frontiers of Earth Science,2020,14(2):430-445. 被引量：3

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