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微波雷达依靠非接触、响应速度快、对自然环境的适应性强等特点在物体运动状态检测中的应用越来越广泛. 常用的调频连续波雷达运动检测算法基于差拍信号频谱的峰值估计, 存在计算量大, 抗干扰能力差等缺点. 本文通过对运动物体的差拍信号做特定频率的离散傅里叶变换, 将变换后的实部和虚部在互相垂直的两个方向上进行叠加, 其合成轨迹近似为椭圆, 求出各轨迹点的相位即可还原物体的运动状态. 该算法无需对每个调频周期的拍信号做频谱分析, 时间复杂度较低. 静止物体的拍信号被处理成了固定的直流信号, 对运动物体的测量不造成影响, 具有抗静止物体干扰的能力. 在雷达中心频率为24 GHz, 带宽为0.15 GHz的条件下对算法进行了验证, 位移测量精度达到0.27 mm, 以500 mm作为位移的测量范围, 线性度达到0.05%. 速度的测量精度为1.11 mm/s.
Real time detection of object motion is widely used in industrial activities and daily life. The contactless measurement is a flexible way, which has no effect on the state of movement of the object. Compared with the optical, ultrasonic and laser sensors, microwave radar has the advantages of high measurement accuracy and being unaffected by the environment such as smoke, dust, fog, and rain. The frequency modulated continuous wave (FMCW) radar is a widely used radar system, the echo of which contains abundant information, and there is no blind zone in the range because the transmitter and receiver work at the same time. The algorithm of movement detection of FMCW radar is commonly based on the peak estimation of signal spectrum, in order to achieve high accuracy, it is necessary to increase the frequency and bandwidth, resulting in high hardware complexity, a large amount of calculation, poor real-time response and poor anti-jamming ability. The proposed algorithm is based on the discrete Fourier transform with specific frequency of the beat signal. The real part and imaginary part of discrete Fourier transform are superposed in two perpendicular directions, and the resultant trajectory is approximately elliptical. The relative displacement of the object is proportional to the cumulative phase change of the corresponding points on the ellipse, the phase of each trajectory point can be calculated to restore the motion state of the object. The proposed algorithm does not need Fourier transform for the beat signal of each chirp, so the time complexity is low. The beat signal of the static object is processed into a fixed direct-current signal, which has no influence on the measurement of the moving object, therefore the algorithm has the ability to resist the interference of the static object. The measurement is limited to relative motion, because the phase obtained is relative. It has great potential applications in the fields of measuring relative displacement, such as mechanical vibration frequency, vital signal detection, mechanical arm control, etc.. An experimental setup with a center frequency of 24 GHz, bandwidth of 0.15 GHz and frequency modulation period of 4 ms is used to test the hypothesis. The experimental results are in good agreement with the theoretical results. The displacement measurement accuracy is 0.27 mm, and the linearity is 0.05% with 500 mm as the displacement measurement range. The measurement accuracy of velocity is 1.11 mm/s. -
Keywords:
- microwave /
- Frequency Modulated Continuous Wave radar /
- motion detection /
- synthetic trajectory
[1] Yang L, Wang B Q, Zhang R H, Zhou H B, Wang R B 2018 IEEE Photonics J 10 1Google Scholar
[2] Yoon J W, Park T 2016 IEEE Trans. Instrum. Meas. 65 1518Google Scholar
[3] 谢田元, 王菊, 王子雄, 马闯, 于洋, 李天宇, 方杰, 于晋龙 2019 68 130601Google Scholar
Xie T Y, Wang J, Wang Z X, Ma C, Yu Y, Li T Y, Fang J, Yu J L 2019 Acta Phys. Sin. 68 130601Google Scholar
[4] Kim S, Cam, Nguyen C 2003 IEEE Trans. Microw. Theory Tech. 51 1724Google Scholar
[5] Kim D K, Kim Y 2019 Sci. Rep. 9 6763Google Scholar
[6] Tudose M L, Anghel A, Cacoveanu R, Datcu M 2018 Sensors 19 82Google Scholar
[7] Pittella E, Nasr I, Pisa S, Cavagnaro M 2016 IEEE Trans. Biomed. Eng. 63 1447Google Scholar
[8] Mercuri M, Lorato I R, Liu Y H, Wieringa F, Hoof C V, Torfs T 2019 Nat. Electron. 2 252Google Scholar
[9] Pan X, Xiang C, Liu S, Yan S 2019 Sensors 19 3176Google Scholar
[10] Nosrati M, Shahsavari S, Lee S, Wang H, Tavassolian N 2019 IEEE Trans. Antennas Propag. 67 2390Google Scholar
[11] Wang G C, Gu C Z, Inoue T, Li C Z 2014 IEEE Trans. Microw. Theory Tech. 62 2812Google Scholar
[12] Schleicher B, Nasr I, Trasser A, Schumacher H 2013 IEEE Trans. Microw. Theory Tech. 61 2076Google Scholar
[13] Qi G Q 2002 International Conference on Signal Processing Beijing, China, October 18–18, p7.
[14] Qi G Q, Jia X L 2001 CIE International Conference on Radar Proceedings Beijing, China, February 1–1, p567
[15] Pauli M, Ayhan S, Scherr S, Rusch C, Zwick T 2012 International Multi-conference on Systems Chemnitz, Germany, March 1–1, 2012 p4
[16] Scherr S, Ayhan S, Fischbach B, Bhutani A, Pauli M, Zwick T 2015 IEEE Trans. Instrum. Meas. 64 1868Google Scholar
[17] Pauli M, Gottel B, Scherr S, Bhutani A, Ayhan S, Winkler W, Zwick T 2017 IEEE Trans. Microw. Theory Tech. 65 1707Google Scholar
[18] Pohl N, Jaeschke T, Aufinger K 2012 IEEE Trans. Microw. Theory Tech. 60 757Google Scholar
[19] Scherr S, Afroz R, Ayhan S, Thomas S, Jaeschke T, Marahrens S, Bhutani A, Pauli M, Pohl N, Zwick T 2017 IEEE Trans. Microw. Theory Tech. 65 3640Google Scholar
[20] Piotrowsky L, Jaeschke T, Kueppers S, Siska J, Pohl N 2019 IEEE Trans. Microw. Theory Tech. 67 5360Google Scholar
[21] Bredendiek C, Pohl N, Jaeschke T, Thomas S, Aufinger K, Bilgic A 2013 European Microwave Integrated Circuit Conference Amsterdam, Netherlands, October 29–30 2012 p309
[22] Jaeschke T, Bredendiek C, Kuppers S, Pohl N 2014 IEEE Trans. Microw. Theory Tech. 62 3582Google Scholar
[23] 科尔曼T H 著 (殷建平 译) 2013 算法导论 (北京: 机械工业出版社) 第25−29页
Cormen T H (translated by Yin J P) 2013 Introduction to Algorithms (Beijing: Machinery Industry Press) pp25−29 (in Chinese)
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图 2 变量
$ {\rm{Re}}_{{k}} $ 和$ {\rm{Im}}_{{k}} $ 的合成轨迹示意图. 红色实心点处在横坐标轴的正半轴上, 代表相位φ = 2jπ, j∈Z的位置Fig. 2. The synthetic ellipse trajectory diagram of variables
$ {\rm{Re}}_{{k}} $ and$ {\rm{Im}}_{{k}} $ . The red solid point is on the positive half axis of abscissa, which represents the position of φ = 2jπ, j∈Z.图 6 计算机模拟在4种不同起始距离下做
$ \lambda /2 $ 位移时的采样点轨迹变化, 起始距离分别为 (a) 800 mm; (b) 1200 mm; (c) 1600 mm; (d) 2000 mmFig. 6. Computer simulation of trajectory change by these sampling points at four different starting distances, the displacement is
$ \lambda /2 $ , the starting distances are: (a) 800 mm; (b) 1200 mm; (c) 1600 mm; (d) 2000 mm.图 7 实验测量在4种不同起始距离下做
$ \lambda /2 $ 位移时的采样点轨迹变化, 起始距离分别为 (a) 800 mm; (b) 1200 mm; (c) 1600 mm; (d) 2000 mmFig. 7. Experimental measurement of trajectory changes by these sampling points at four different starting distances, the displacement is
$ \lambda /2 $ , the starting distances are: (a) 800 mm; (b) 1200 mm; (c) 1600 mm; (d) 2000 mm.表 1 与其他算法的比较
Table 1. Comparison of this work with other methods.
文献 算法 时间复杂度* 测量环境 测量内容 [21] 插值法 O($N{\,\mathrm{l}\mathrm{o}\mathrm{g} }_{2}N$) 环境简单, 被测物几乎是唯一的散射源 绝对距离 [22] 补零法 O($M \log_{2}M$) 绝对距离 [19] CZT O($N\log_{2}N$)+ O($ {N}^{3/2} $) 绝对距离 [20] 插值法+补零法 O($M\log_{2}M$) 绝对距离 [16] CZT O($N\log_2 N$)+ O($ {N}^{3/2} $) 被测物及雷达封装在波导内 绝对距离 本算法 O(N) 无其他运动物体 相对距离 注: *N 为一个调频周期内拍信号的采样点数目. M 为补零后的采样点数目. 表 2 金属板运动的测量结果
Table 2. Measurement results of metal plate movement.
设定速度
/(mm·s–1)位移设
定值/mm位移测量值 平均
值/mm平均值的
偏差/mm最大
偏差/mm标准
差/mm10 300 300.10 0.10 0.26 0.15 400 399.91 –0.09 0.24 0.15 500 499.93 –0.07 0.25 0.14 20 300 299.95 –0.05 0.21 0.12 400 400.08 0.08 0.24 0.14 500 500.05 0.05 0.27 0.13 30 300 300.09 0.09 0.26 0.15 400 399.96 –0.04 0.21 0.12 500 499.96 –0.04 0.23 0.12 -
[1] Yang L, Wang B Q, Zhang R H, Zhou H B, Wang R B 2018 IEEE Photonics J 10 1Google Scholar
[2] Yoon J W, Park T 2016 IEEE Trans. Instrum. Meas. 65 1518Google Scholar
[3] 谢田元, 王菊, 王子雄, 马闯, 于洋, 李天宇, 方杰, 于晋龙 2019 68 130601Google Scholar
Xie T Y, Wang J, Wang Z X, Ma C, Yu Y, Li T Y, Fang J, Yu J L 2019 Acta Phys. Sin. 68 130601Google Scholar
[4] Kim S, Cam, Nguyen C 2003 IEEE Trans. Microw. Theory Tech. 51 1724Google Scholar
[5] Kim D K, Kim Y 2019 Sci. Rep. 9 6763Google Scholar
[6] Tudose M L, Anghel A, Cacoveanu R, Datcu M 2018 Sensors 19 82Google Scholar
[7] Pittella E, Nasr I, Pisa S, Cavagnaro M 2016 IEEE Trans. Biomed. Eng. 63 1447Google Scholar
[8] Mercuri M, Lorato I R, Liu Y H, Wieringa F, Hoof C V, Torfs T 2019 Nat. Electron. 2 252Google Scholar
[9] Pan X, Xiang C, Liu S, Yan S 2019 Sensors 19 3176Google Scholar
[10] Nosrati M, Shahsavari S, Lee S, Wang H, Tavassolian N 2019 IEEE Trans. Antennas Propag. 67 2390Google Scholar
[11] Wang G C, Gu C Z, Inoue T, Li C Z 2014 IEEE Trans. Microw. Theory Tech. 62 2812Google Scholar
[12] Schleicher B, Nasr I, Trasser A, Schumacher H 2013 IEEE Trans. Microw. Theory Tech. 61 2076Google Scholar
[13] Qi G Q 2002 International Conference on Signal Processing Beijing, China, October 18–18, p7.
[14] Qi G Q, Jia X L 2001 CIE International Conference on Radar Proceedings Beijing, China, February 1–1, p567
[15] Pauli M, Ayhan S, Scherr S, Rusch C, Zwick T 2012 International Multi-conference on Systems Chemnitz, Germany, March 1–1, 2012 p4
[16] Scherr S, Ayhan S, Fischbach B, Bhutani A, Pauli M, Zwick T 2015 IEEE Trans. Instrum. Meas. 64 1868Google Scholar
[17] Pauli M, Gottel B, Scherr S, Bhutani A, Ayhan S, Winkler W, Zwick T 2017 IEEE Trans. Microw. Theory Tech. 65 1707Google Scholar
[18] Pohl N, Jaeschke T, Aufinger K 2012 IEEE Trans. Microw. Theory Tech. 60 757Google Scholar
[19] Scherr S, Afroz R, Ayhan S, Thomas S, Jaeschke T, Marahrens S, Bhutani A, Pauli M, Pohl N, Zwick T 2017 IEEE Trans. Microw. Theory Tech. 65 3640Google Scholar
[20] Piotrowsky L, Jaeschke T, Kueppers S, Siska J, Pohl N 2019 IEEE Trans. Microw. Theory Tech. 67 5360Google Scholar
[21] Bredendiek C, Pohl N, Jaeschke T, Thomas S, Aufinger K, Bilgic A 2013 European Microwave Integrated Circuit Conference Amsterdam, Netherlands, October 29–30 2012 p309
[22] Jaeschke T, Bredendiek C, Kuppers S, Pohl N 2014 IEEE Trans. Microw. Theory Tech. 62 3582Google Scholar
[23] 科尔曼T H 著 (殷建平 译) 2013 算法导论 (北京: 机械工业出版社) 第25−29页
Cormen T H (translated by Yin J P) 2013 Introduction to Algorithms (Beijing: Machinery Industry Press) pp25−29 (in Chinese)
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