Preliminary Results of Low Frequency Ultra-wideband Bistatic SAR Experiment

被引:0
作者
Xie, Hongtu [1 ,3 ]
Shi, Shaoying [1 ]
Wang, Rongyi [2 ]
Rui, Li [2 ]
Xie, Chao [1 ]
Fang, Qunle [1 ]
Wang, Feng [1 ]
An, Daoxiang [3 ]
Zhou, Zhimin [3 ]
Wang, Guoqian [4 ]
机构
[1] Air Force Early Warning Acad, Wuhan, Hubei, Peoples R China
[2] PLA, Unit 92664, Qingdao, Peoples R China
[3] Natl Univ Def Technol, Coll Elect Sci & Engn, Changsha, Hunan, Peoples R China
[4] Hunan Inst Tradit Chinese Med, Affiliated Hosp, Changsha, Hunan, Peoples R China
来源
2017 2ND INTERNATIONAL CONFERENCE ON FRONTIERS OF SENSORS TECHNOLOGIES (ICFST) | 2017年
基金
中国国家自然科学基金;
关键词
low frequency; ultra-wideband; bistatic synthetic aperture radar; imaging experiment; preliminary results; SYNTHETIC-APERTURE RADAR; DOMAIN ALGORITHMS;
D O I
暂无
中图分类号
TM [电工技术]; TN [电子技术、通信技术];
学科分类号
0808 ; 0809 ;
摘要
The low frequency ultra-wideband bistatic synthetic aperture radar (LF UWB BSAR) system has the well ability of penetrating the foliage, high-resolution imaging and providing the increased information, thus it is able to detect the vehicle-size targets concealed in the forest. Initial experiment of the LF UWB BSAR system has been carried out in late 2015. In this experiment, both monostatic and bistatic data were collected simultaneously by operating the vehicle-based radar in a strip-map SAR mode, in conjunction with the stationary ground-based receiver. This paper gives an overview of the LF UWB BSAR system, and then discusses the experiment and data processing, finally presents the initial experimental results.
引用
收藏
页码:331 / 335
页数:5
相关论文
共 50 条
[21]   A Low-Profile Ultra-Wideband Directional Antenna [J].
Lin, Shu ;
Mao, Yu ;
Bi, Yan-di ;
Liu, Shou-lan ;
Zhang, Hao-tian ;
Yang, Cai-tian .
2017 INTERNATIONAL SYMPOSIUM ON ANTENNAS AND PROPAGATION (ISAP 2017), 2017,
[22]   Ultra-wideband Low-Detectable Coding Metasurface [J].
LIU Guanghong ;
LIU Jiayi ;
ZHAO Shan ;
SU Jianxun .
ChineseJournalofElectronics, 2019, 28 (06) :1265-1270
[23]   A low complexity RAKE receiver for ultra-wideband systems [J].
Li, W ;
Zhong, J ;
Gulliver, TA .
VTC2005-FALL: 2005 IEEE 62ND VEHICULAR TECHNOLOGY CONFERENCE, 1-4, PROCEEDINGS, 2005, :1393-1396
[24]   Ultra-wideband Low-Detectable Coding Metasurface [J].
Liu, Guanghong ;
Liu, Jiayi ;
Zhao, Shan ;
Su, Jianxun .
CHINESE JOURNAL OF ELECTRONICS, 2019, 28 (06) :1265-1270
[25]   Reconfigurable active frequency selective surface for ultra-wideband applications [J].
Zhao, Yulin ;
Fu, Jiahui ;
Liang, Zhiming ;
Wang, Zhefei ;
Zhang, Zhiyi ;
Lv, Bo ;
Chen, Wan .
INTERNATIONAL JOURNAL OF RF AND MICROWAVE COMPUTER-AIDED ENGINEERING, 2020, 30 (07)
[26]   A New Ultra-Wideband High-Frequency Channel Model [J].
Zhao, Di ;
Wang, Hongqing ;
Ji, Xiang ;
Xing, Chengwen ;
Fei, Zesong ;
Wang, Hualei .
2015 IEEE CHINA SUMMIT & INTERNATIONAL CONFERENCE ON SIGNAL AND INFORMATION PROCESSING, 2015, :923-927
[27]   Ultra-wideband Frequency Selective Surface at K and Ka Band [J].
Liang Bing-yuan ;
Xue Zheng-hui ;
Li Wei-ming ;
Ren Wu .
2013 IEEE INTERNATIONAL CONFERENCE ON MICROWAVE TECHNOLOGY & COMPUTATIONAL ELECTROMAGNETICS (ICMTCE), 2013, :55-57
[28]   Reconfigurable Active Frequency Selective Surface for Ultra-Wideband Applications [J].
Zhao, Yulin ;
Fu, Jiahui ;
Liang, Zhiming ;
Wang, Zhefei ;
Zhang, Zhiyi ;
Lv, Bo ;
Chen, Wan .
2019 CROSS STRAIT QUAD-REGIONAL RADIO SCIENCE AND WIRELESS TECHNOLOGY CONFERENCE (CSQRWC), 2019,
[29]   Absolute phase determination for low-frequency ultra-wideband synthetic aperture radar interferometry [J].
Xu, Junyi ;
An, Daoxiang ;
Huang, Xiaotao ;
Wang, Guangxue .
IET RADAR SONAR AND NAVIGATION, 2016, 10 (02) :426-433
[30]   Design of ultra-wideband antenna using tapered slot for low-end frequency extension [J].
Dang, Tao ;
Zheng, Hongxing ;
Wang, Lu ;
Cui, Wenjie ;
Wang, Guangming .
INTERNATIONAL JOURNAL OF RF AND MICROWAVE COMPUTER-AIDED ENGINEERING, 2019, 29 (02)
12345