基于跟踪脉冲的MIMO雷达多目标微动特征提取

罗迎 龚逸帅 陈怡君 张群

罗迎, 龚逸帅, 陈怡君, 张群. 基于跟踪脉冲的MIMO雷达多目标微动特征提取[J]. 雷达学报, 2018, 7(5): 575-584. doi: 10.12000/JR18035
引用本文: 罗迎, 龚逸帅, 陈怡君, 张群. 基于跟踪脉冲的MIMO雷达多目标微动特征提取[J]. 雷达学报, 2018, 7(5): 575-584. doi: 10.12000/JR18035
Luo Ying, Gong Yishuai, Chen Yijun, Zhang Qun. Multi-target Micro-motion Feature Extraction Based on Tracking Pulses in MIMO Radar[J]. Journal of Radars, 2018, 7(5): 575-584. doi: 10.12000/JR18035
Citation: Luo Ying, Gong Yishuai, Chen Yijun, Zhang Qun. Multi-target Micro-motion Feature Extraction Based on Tracking Pulses in MIMO Radar[J]. Journal of Radars, 2018, 7(5): 575-584. doi: 10.12000/JR18035

基于跟踪脉冲的MIMO雷达多目标微动特征提取

DOI: 10.12000/JR18035
基金项目: 国家自然科学基金(61571457,61631019)
详细信息
    作者简介:

    陈怡君(1989–),女,陕西西安人,现为武警工程大学信息工程学院讲师,研究方向为认知成像与目标识别。E-mail: chenyijun519@126.com

    通讯作者:

    罗迎  luoying2002521@163.com

Multi-target Micro-motion Feature Extraction Based on Tracking Pulses in MIMO Radar

Funds: The National Natural Science Foundation of China (61571457, 61631019)
  • 摘要: 微动特征是空间目标识别的重要特征信息之一。然而,现有的多功能多输入多输出(Multi-Input Multi-Output, MIMO)雷达通常需要在完成目标搜索和跟踪任务之后为目标微动特征提取分配大量连续的时间资源,导致目标识别实时性能和雷达系统整体工作性能均不高。针对该问题,该文提出了一种基于跟踪脉冲的MIMO雷达多目标微动特征提取方法。首先依据各目标的方位信息对MIMO雷达发射波形进行设计,为不同方向目标同时发射跟踪脉冲;在此基础上,综合考虑目标微动特征提取性能以及目标跟踪性能的需求,对跟踪脉冲的发射时间序列进行优化设计;最后,直接利用窄带跟踪脉冲实现对不同方向目标微动特征的同时提取,无需再为目标微动特征提取分配额外的时间资源,有效提升目标识别实时性和雷达工作效率。仿真实验表明,在信噪比大于–10 dB时,所提方法能够实现多目标微动特征的准确提取,具有良好的有效性和鲁棒性。

     

  • 图  1  MIMO雷达发射阵列示意图

    Figure  1.  Transmit array of MIMO radar

    图  2  旋转目标的几何模型

    Figure  2.  Geometry of a rotating target

    图  3  算法流程

    Figure  3.  Flow chart of the algorithm

    图  4  发射方向图

    Figure  4.  The transmit beampattern

    图  5  无噪声条件下文献[18]方法重构的时频分布

    Figure  5.  The reconstructed time-frequency distribution using method in Ref. [18] without noise

    图  7  0°方向所提方法重构的时频分布

    Figure  7.  The reconstructed time-frequency distribution in 0° direction using the proposed method

    图  6  –30°方向所提方法重构的时频分布

    Figure  6.  The reconstructed time-frequency distribution in –30° direction using the proposed method

    图  8  算法性能随信噪比变化曲线

    Figure  8.  The performance curve versus SNR

    表  1  目标参数

    Table  1.   The parameters of the targets

    目标方位(°) 参考点坐标(km) 旋转角速度 $\left( {\rm{rad}} \cdot {{\rm{s}}^{{\rm{ - 1}}}}\right) $ 目标散射点坐标(m)
    –30 (15, 26, 0) ${\rm{(}}{π} {\rm{,}}{π} {\rm{/2,}}{π} {\rm{)}}$ $(0,0,0),({\rm{1}},{\rm{1}},{\rm{0}}),( - {\rm{1}}, - {\rm{1}},{\rm{0}})$
    0 (0, 40, 0) ${\rm{(0,0,}}{π} {\rm{)}}$ $(2,0,0),( - 2,0,0),(0, - 2,0),(0,2,0)$
    下载: 导出CSV

    表  2  文献[18]方法目标微动特征提取结果

    Table  2.   The micro-motion features of targets obtained by method in Ref. [18]

    目标方向(°) 特征参数序号 目标散射点坐标 ${{r}_0}$ (m) 旋转角速度 ${{w}}$ $\left( {\rm{rad}} \cdot {{\rm{s}}^{{\rm{ - 1}}}}\right) $ 系数A
    –30 1 $(0.1 \ 0 \ - 0.1)$ $(3.14 \ 1.57 \ 3.14)$ 30.40
    2 $({\rm{1 \ 1 \ 0}})$ $(3.14 \ 1.57 \ 3.14)$ 27.07
    3 $( - {\rm{1.0 }}\ - {\rm{1.1}} \ {\rm{ 0}})$ $(3.14 \ 1.57 \ 3.14)$ 25.11
    4 $({\rm{0}}{\rm{.3 }}\ 0\ {\rm{ 0}})$ $(3.14 \ 1.57 \ 3.14)$ 5.96
    5 $(1.5 \ - {\rm{1.2}}\ {\rm{0}})$ $(2.83 \ 1.57 \ 3.14)$ 4.29
    0 1 $( - 1.8 \ 0.1 \ 0)$ $(0.31 \ 0 \ 2.51)$ 29.15
    2 $(0.1 \ - 1.9 \ 0)$ $(0.31 \ 0 \ 2.51)$ 28.10
    3 $(0.5 \ 2.4 \ 0)$ $(0.31 \ 0 \ 2.51)$ 24.27
    4 $(2.6 \ - 0.2 \ 0)$ $(0.31 \ 0 \ 2.51)$ 23.31
    5 $( - 1.9 \ - {\rm{0.4 }}\ {\rm{0}})$ $(0 \ 0.31 \ 2.83)$ 3.15
    下载: 导出CSV

    表  3  无噪声条件下所提方法目标微动特征提取结果

    Table  3.   The micro-motion features of targets obtained by the proposed method without noise

    目标方向(°) 特征参数序号 目标散射点坐标 ${{r}_0}$ (m) 旋转角速度 ${{w}}$ ( ${\rm{rad}} \cdot {{\rm{s}}^{{\rm{ - 1}}}}$) 系数A
    –30 1 $(0.1 \ 0 \ - 0.1)$ $(3.14 \ 1.57 \ 3.14)$ 27.23
    2 $({\rm{1 \ 1 \ 0}})$ $(3.14 \ 1.57 \ 3.14)$ 26.47
    3 $( - {\rm{1.0}} \ - {\rm{1.1}} \ {\rm{ 0}})$ $(3.14 \ 1.57 \ 3.14)$ 26.01
    4 $( - 1.3 \ - {\rm{1.2}}\ {\rm{0}})$ $(2.83 \ 1.57 \ 3.14)$ 6.40
    5 $({\rm{0}}{\rm{.3 }} \ 0 \ {\rm{ 0}})$ $(3.14 \ 1.88 \ 3.14)$ 6.06
    0 1 $(2.0 \ 0.1 \ 0)$ $(0 \ 0 \ 3.14)$ 28.63
    2 $( - 1.9 \ 0 \ 0)$ $(0 \ 0 \ 3.14)$ 28.39
    3 $(0.1 \ - 2.0 \ 0)$ $(0 \ 0 \ 3.14)$ 27.71
    4 $(0 \ 1.9 \ 0)$ $(0 \ 0 \ 3.14)$ 27.19
    5 $(1.8 \ 0.1 \ 0.3)$ $(0 \ 0.31 \ 2.83)$ 6.72
    下载: 导出CSV

    表  4  SNR=–10 dB条件下所提方法目标微动特征提取结果

    Table  4.   The micro-motion features of targets obtained by the proposed method when SNR=–10 dB

    目标方向(°) 特征参数序号 目标散射点坐标 ${{r}_0}$ (m) 旋转角速度 ${{w}}$ $\left( {\rm{rad}} \cdot {{\rm{s}}^{{\rm{ - 1}}}}\right) $ 系数A
    –30 1 $(0.1 \ 0 \ - 0.1)$ $(3.14 \ 1.57 \ 3.14)$ 26.83
    2 $({\rm{1 \ 1 \ 0}})$ $(3.14 \ 1.57 \ 3.14)$ 25.48
    3 $( - {\rm{1.0}} - {\rm{1.1}}\ {\rm{ 0}})$ $(3.14 \ 1.57 \ 3.14)$ 25.09
    4 $( - 1.3 \ - {\rm{1.2}}\ {\rm{ 0}})$ $(2.83 \ 1.57 \ 3.14)$ 7.78
    5 $({\rm{0}}{\rm{.3 }}\ 0 \ {\rm{ 0}})$ $(3.14 \ 1.88 \ 3.14)$ 7.31
    0 1 $(2.0 \ 0.1 \ 0)$ $(0 \ 0 \ 3.14)$ 27.52
    2 $( - 1.9 \ 0 \ 0)$ $(0 \ 0 \ 3.14)$ 27.28
    3 $(0.1 \ - 2.0 \ 0)$ $(0 \ 0 \ 3.14)$ 26.59
    4 $(0 \ 1.9 \ 0)$ $(0 \ 0 \ 3.14)$ 26.08
    5 $(1.8 \ 0.1 \ 0.3)$ $(0 \ 0.31 \ 2.83)$ 9.15
    下载: 导出CSV

    表  5  SNR=–15 dB条件下所提方法目标微动特征提取结果

    Table  5.   The micro-motion features of targets obtained by the proposed method when SNR=–15 dB

    目标方向(°) 特征参数序号 目标散射点坐标 ${{r}_0}$ (m) 旋转角速度 ${{w}}$ $\left( {\rm{rad}} \cdot {{\rm{s}}^{{\rm{ - 1}}}}\right) $ 系数A
    –30 1 $(0.2 \ 0.1 \ - 0.1)$ $(3.14 \ 1.57 \ 3.14)$ 25.73
    2 $({\rm{0.9}}{\rm{ \ 1.0 \ 0}})$ $(3.14 \ 1.57 \ 3.14)$ 23.27
    3 $( - {\rm{1}}{\rm{.2 }}\ - {\rm{1.0}}\ {\rm{0.1}})$ $(3.14 \ 1.57 \ 3.14)$ 22.16
    4 $( - 1.5 \ - {\rm{1.3}}\ {\rm{ 0}})$ $(2.83 \ 1.57 \ 3.14)$ 15.04
    5 $({\rm{0}}{\rm{.8 }} \ 0 \ {\rm{ 0}}{\rm{.5}})$ $(2.83 \ 2.19 \ 3.14)$ 10.58
    0 1 $(2.2 \ - 0.1 \ 0)$ $(0 \ 0 \ 3.14)$ 26.81
    2 $( - 2.0 \ 0.1 \ 0)$ $(0 \ 0 \ 3.14)$ 25.35
    3 $(0.2 \ - 1.8 \ 0)$ $(0 \ 0 \ 3.14)$ 25.19
    4 $(0.1 \ 1.8 \ 0.2)$ $(0 \ 0 \ 3.14)$ 24.07
    5 $(1.7 \ 0.3 \ 0.4)$ $(0 \ 0.31 \ 2.83)$ 13.15
    下载: 导出CSV
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出版历程
  • 收稿日期:  2018-04-25
  • 修回日期:  2018-06-02
  • 网络出版日期:  2018-10-28

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