Study on Deep Learning in Radar
Wang Jun* Zheng Tong Lei Peng Wei Shaoming
(School of Electronic and Information Engineering, Beijing University of Aeronautics and Astronautics, Beijing 100191, China)
Abstract Electromagnetic waves are transmitted by radars and reflected by different objects, and radar signal processing is highly significant as its analyses can lead to the acquisition of important information such as the situation and radial movement speed. Moreover, deep learning has gained much attention in several fields, and it can be utilized to implement radar signal processing. Compared with the traditional methods, deep learning can realize automatic feature extraction and yield highly accurate results; hence, in this paper, the application of deep learning algorithm in radar signal processing is studied. In addition, the study directions in radar signal processing are summarized into overfitting and interpretation. Thus, these two issues are being considered.
Key words : Radar
Deep learning
Signal processing
Received: 2018-05-22;
Published: 2018-08-16
Fund: The National Natural Science Foundation of China (61501011, 61671035)
Cite this article:
Wang Jun,Zheng Tong,Lei Peng et al. Study on Deep Learning in Radar[J]. JOURNAL OF RADARS, 2018, 7(4): 395-411.
[1]
Liu Yuqi, Yi Jianxin, Wan Xianrong, Cheng Feng, Rao Yunhua, Gong Ziping. Experimental Research on Micro-Doppler Effect of Multi-rotor Drone with Digital Television Based Passive Radar
[2]
Zhao Feixiang, Liu Yongxiang, Huo Kai. A Radar Target Classification Algorithm Based on Dropout Constrained Deep Extreme Learning Machine
[3]
Zhang Qun, Hu Jian, Luo Ying, Chen Yijun. Research Progresses in Radar Feature Extraction, Imaging, and Recognition of Target with Micro-motions
[4]
Hui Ye, Bai Xueru. RID Image Series-based High-resolution Three-dimensional Imaging of Micromotion Targets
[5]
Su Ningyuan, Chen Xiaolong, Guan Jian, Mou Xiaoqian, Liu Ningbo. Detection and Classification of Maritime Target with Micro-motion Based on CNNs
[6]
Luo Ying, Gong Yishuai, Chen Yijun, Zhang Qun. Multi-target Micro-motion Feature Extraction Based on Tracking Pulses in MIMO Radar
[7]
Yu Lingjuan, Wang Yadong, Xie Xiaochun, Lin Yun, Hong Wen. SAR ATR Based on FCNN and ICAE
[8]
Hu Cheng, Dong Xichao, Li Yuanhao. Atmospheric Effects on the Performance of Geosynchronous Orbit SAR Systems
[9]
Wang Pei, Sun Huifeng, Yu Weidong. A Novel Wireless Internal Calibration Method of Spaceborne SAR
[10]
Wu Yufeng, Ye Shaohua, Feng Dazheng. Intra-pulse Spotlight SAR Imaging Method Based on Azimuth Phase Coding
[11]
Zhao Bo, Huang Lei, Zhou Hanfei, Zhang Liang, Li Qiang, Huang Min. 1-bit SAR Imaging Method Based on Single-frequency Time-varying Threshold
[12]
Ji Guangyu, Dong Yongwei, Bu Yuncheng, Li Yanlei, Zhou Liangjiang, Liang Xingdong. Multi-band SAR Coherent Change Detection Method Based on Coherent Representation Differences of Targets
[13]
Sun Xiang, Song Hongjun, Wang Robert, Li Ning. POA Correction Method Using High-resolution Full-polarization SAR Image
[14]
Hao Tianduo, Cui Chen, Gong Yang, Sun Congyi. Waveform Design for Cognitive Radar Under Low PAR Constraints by Convex Optimization
[15]
Wang Benjing, Yi Jianxin, Wan Xianrong, Dan Yangpeng. Inter-frame Ambiguity Analysis and Suppression of LTE Signal for Passive Radar
2018, Vol. 7 
