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弹道靶利用二级轻气炮将模型加速到高超声速状态, 模型在靶室内超高速飞行时形成等离子体尾迹. 为实现高超声速模型尾迹电子密度径向二维分布诊断, 利用七通道微波干涉仪测量系统获得了高超声速模型尾迹截面不同位置处平均电子密度. 该系统采用一发七收的方式, 实现平面波照射等离子体及平面波接收, 天线波束可完全覆盖尾迹径向范围. 多通道微波干涉仪数据处理过程常将等离子体视为分层介质, 考虑到分层界面上折射效应的影响, 本研究利用射线追踪方式建立电磁传播模型, 结合测量数据建立目标函数, 通过遗传算法优化来反演高超声速模型尾迹电子密度径向二维分布. 该数据处理方法的电子密度反演结果与相同来流条件下的数值模拟结果对比吻合较好, 初步验证了该方法的有效性. 分析了分层模型对电子密度分布特性的影响, 结果表明利用七层模型对尾迹建模效果最佳, 且适用于不同厚度尾迹, 最大化利用接收通道数, 确保了计算精度. 利用该方法实现弹道靶高超声速球模型尾迹电子密度二维分布诊断, 并给出了给定实验状态下模型尾迹电子密度二维分布的一些规律.The ballistic target uses a two-stage light gas gun to launch the model into a hypersonic state, and the model forms a plasma wake when flying at a hypersonic speed in the target chamber. In order to obtain the radial two-dimensional distribution of transient plasma electron density in the wake of hypervelocity model, a seven-channel Ka-band microwave interferometer measuring system is developed. In the transceiver system, a transmitting antenna achieves the plane wave irradiation plasma, and a seven-port array antenna is used to receive plane waves which are passing through the plasma: the antenna beam can completely cover the radial range of the wake. The shortest response time of measuring system is 1 s, and electron density measurement range of the interferometer measuring system is 1011–1013/cm3 . The plasma is often treated as layered medium in data processing of multichannel microwave interferometer. Taking into consideration the effect of refraction on the stratified interface in this work, the ray tracing (RT) method is used to establish the electromagnetic propagation model. Combined with the measurement data to construct the objective function, the genetic algorithm (GA) is used to invert the radial two-dimensional distribution of the electron density under different test conditions. The result shows good agreement with the numerical simulation under the same test state, which proves the the data processing method reliable. Then, the influence of the layered model on the calculation result is analyzed, which shows that the seven-layer model is suitable for the wake modeling under given experimental conditions, and thus maximizing the number of receiving channels and ensuring the accuracy. The RT method is used for the first time to achieve the two-dimensional distribution of electron density in the wake of hypervelocity projectile, and some rules of two-dimensional electron density distribution of the hypersonic model under given experimental conditions are realized.
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Keywords:
- wake of hypervelocity model /
- seven channels microwave interferometer /
- ray tracing /
- two-dimensional distribution
[1] 于哲峰, 孙良奎, 马平, 杨益兼, 张志成, 黄洁 2017 红外 38 039Google Scholar
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Wu Y, Bai S B, Wang J Y, Chen J P, Ni X W 2007 Optoelectron. Technol. 27 49Google Scholar
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Wang Y F, Zhu X M, Zhang M Z, Meng S F, Jia J W, Chai H, Wang Y, Ning Z X 2021 Acta Phys. Sin. 70 095211Google Scholar
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Wu J Z, Tang J E, Dong Y E, Zhang G F, Wang Y H 2012 Acta Phys. Sin 61 195208Google Scholar
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[8] Jobes F C, Mansfield D K 1992 Rev. Sci. Instrum. 63 5154Google Scholar
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[14] 易臻 2006 制造业自动化 28 091Google Scholar
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[19] 叶民友, 郭文康, 范叔平 1991 核聚变与等离子体物理 11 185Google Scholar
Ye M Y, Guo W K, Fan S P 1991 Nucl. Fusion Plasma Phys. 11 185Google Scholar
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图 2
$P = 40000{\text{ }}{\rm{Pa}}, V = 5.83{\text{ km}}/{\text{s}}$ 钢球模型尾迹电子密度分布 (a) 电子密度流场; (b) 不同轴向位置电子密度径向二维分布Fig. 2. The wake of ball electron density distribution (
$P = 40000{\text{ }}{\rm{Pa}}, V = 5.83{\text{ km}}/{\text{s}}$ ): (a) The flow field of electron density; (b) radial two-dimensional distribution of electron density at different axial positions.图 6 径向不同位置电子密度随轴向距离的分布 (a) ϕ12 mm 钢球, P = 40000 Pa, V = 5.83 km/s; (b) ϕ12 mm 钢球, P = 20000 Pa, V = 5.80 km/s; (c) ϕ15 mm Al2O3球, P = 40000 Pa, V = 4.72 km/s
Fig. 6. The electron density at different radial positions distribution with axial distance: (a) Steel ball of ϕ12 mm, P = 40000 Pa, V = 5.83 km/s; (b) steel ball of ϕ12 mm, P = 20000 Pa, V = 5.80 km/s; (c) Al2O3 ball of ϕ15 mm, P = 40000 Pa, V = 4.72 km/s.
图 7 x = 10
$ 0\phi $ 电子密度径向二维分布 (a) ϕ12 mm 钢球, P = 40000 Pa, V = 5.83 km/s; (b) ϕ12 mm 钢球, P = 20000 Pa, V = 5.80 km/s; (c) ϕ15 mm Al2O3球, P = 40000 Pa, V = 4.72 km/sFig. 7. The radial two-dimensional distribution of plasma electron density (x = 100
$ \phi $ ): (a) ϕ12 mm 钢球, P = 40000 Pa, V = 5.83 km/s; (b) ϕ12 mm 钢球, P = 20000 Pa, V = 5.80 km/s; (c) ϕ15 mm Al2O3球, P = 40000 Pa, V = 4.72 km/s.图 8 x = 50
$ \phi $ 电子密度径向二维分布 (a) ϕ12 mm 钢球, P = 40000 Pa, V = 5.83 km/s; (b) ϕ12 mm 钢球, P = 20000 Pa, V = 5.80 km/s; (c) ϕ15 mm Al2O3球, P = 40000 Pa, V = 4.72 km/sFig. 8. The radial two-dimensional distribution of plasma electron density (x = 50
$ \phi $ ): (a) ϕ12 mm 钢球, P = 40000 Pa, V = 5.83 km/s; (b) ϕ12 mm 钢球, P = 20000 Pa, V = 5.80 km/s; (c) ϕ15 mm Al2O3球, P 40000 Pa, V = 4.72 km/s.图 9 x = 10
$ \phi $ 电子密度径向二维分布 (a) ϕ12 mm 钢球, P = 40000 Pa, V = 5.83 km/s; (b) ϕ12 mm 钢球, P = 20000 Pa, V = 5.80 km/s; (c) ϕ15 mm Al2O3球, P = 40000 Pa, V = 4.72 km/sFig. 9. The radial two-dimensional distribution of plasma electron density (x = 10
$ \phi $ ): (a) ϕ12 mm 钢球, P = 40000 Pa, V = 5.83 km/s; (b) ϕ12 mm 钢球, P = 20000 Pa, V = 5.80 km/s; (c) ϕ15 mm Al2O3球, P = 40000 Pa, V = 4.72 km/s. -
[1] 于哲峰, 孙良奎, 马平, 杨益兼, 张志成, 黄洁 2017 红外 38 039Google Scholar
Yu Z F, Sun L K, Ma P, Yang Y J, Zhang Z C, Huang J 2017 Infrared 38 039Google Scholar
[2] 池凌飞, 林揆训, 姚若河, 林璇英, 余楚迎, 余云鹏 2001 50 1313Google Scholar
Chi L F, Lin K X, Yao R H, Lin X Y, Yu C Y, Yu Y P 2001 Acta Phys. Sin. 50 1313Google Scholar
[3] 吴莹, 白顺波, 王俊彦, 陈建平, 倪晓武 2007 光电子技术 27 49Google Scholar
Wu Y, Bai S B, Wang J Y, Chen J P, Ni X W 2007 Optoelectron. Technol. 27 49Google Scholar
[4] 吴蓉, 李燕, 朱顺官, 冯红艳, 张琳, 王俊德 2008 光谱学与光谱分析 28 731Google Scholar
Wu R, Li Y, Zhu S G, Feng H Y, Zhang L, Wang J D 2008 Spectrosc. Spectral Anal. 28 731Google Scholar
[5] 王彦飞, 朱悉铭, 张明志, 孟圣峰, 贾军伟, 柴昊, 王旸, 宁中喜 2021 70 095211Google Scholar
Wang Y F, Zhu X M, Zhang M Z, Meng S F, Jia J W, Chai H, Wang Y, Ning Z X 2021 Acta Phys. Sin. 70 095211Google Scholar
[6] 武晋泽, 唐晋娥, 董有尔, 张国峰, 王彦华 2012 61 195208Google Scholar
Wu J Z, Tang J E, Dong Y E, Zhang G F, Wang Y H 2012 Acta Phys. Sin 61 195208Google Scholar
[7] Rishabhkumar M N, Nandurbarkar A B, Buch J U 2017 International Conference on Inventive Computing and Informatics Coimbatore, India, November 23–24, 2017 pp267–272
[8] Jobes F C, Mansfield D K 1992 Rev. Sci. Instrum. 63 5154Google Scholar
[9] Ohler G S, Gilchrist E B, Gallimore D A 1995 IEEE Trans. Plasma Sci. 23 428Google Scholar
[10] Ghaderi M, Moradi G, Mousavi P 2018 IEEE Trans. Plasma Sci. 47 451Google Scholar
[11] Atrey P, Pujara D, Mukherjee S, Rakesh L 2019 IEEE Trans. Plasma. Sci. 47 1316Google Scholar
[12] Yoshikawa M, Matsumoto T, Shima Y, Negishi S, Imai T 2008 Rev. Sci. Instrum. 79 2281Google Scholar
[13] Eiichirou K, Lin Y H, Atsushi M, Yasushi N, Cheng C Z 2014 Rev. Sci. Instrum. 85 023507Google Scholar
[14] 易臻 2006 制造业自动化 28 091Google Scholar
Yi Z 2006 Manuf. Autom. 28 091Google Scholar
[15] 马平, 石安华, 杨益兼, 于哲峰, 梁世昌, 黄洁 2017 66 102401Google Scholar
Ma P, Shi A H, Yang Y J, Yu Z F, Liang S C, Huang J 2017 Acta Phys. Sin. 66 102401Google Scholar
[16] 马昊军, 王国林, 罗杰, 刘丽萍, 潘德贤, 张军, 刑英丽, 唐飞 2018 67 025201Google Scholar
Ma H J, Wang G L, Luo J, Liu L P, Pan D X, Zhang J, Xing Y L, Tang F 2018 Acta Phys. Sin. 67 025201Google Scholar
[17] 肖礼康, 唐璞, 陈波, 万莉莉, 何子远, 马平 2017 兵器装备工程学报 38 44Google Scholar
Xiao L K, Tang P, Chen B, Wang L L, He Z Y, Ma P 2017 J. Ordnance Equip. Eng. 38 44Google Scholar
[18] Shi P W, Shi Z B, Chen W, Zhong W L, Yang Z C, Jiang M, Zhang B Y, Li Y G, Yu L M, Liu Z T, Ding X T 2016 Plasma Sci. Technol. 18 708Google Scholar
[19] 叶民友, 郭文康, 范叔平 1991 核聚变与等离子体物理 11 185Google Scholar
Ye M Y, Guo W K, Fan S P 1991 Nucl. Fusion Plasma Phys. 11 185Google Scholar
[20] 何璐, 董晓龙, 张祥坤 2016 空间科学学报 36 358Google Scholar
He L, Dong X L, Zhang X K 2016 Chin. J. Space Sci. 36 358Google Scholar
[21] 江少恩, 刘忠礼, 唐道源, 郑志坚 1999 光学学报 19 660Google Scholar
Jiang S E, Liu Z L, Tang D Y, Zheng Z J 1999 Acta Opt. Sin. 19 660Google Scholar
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