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针对临近空间高超声速飞行器目标探测与识别研究的需求, 开展了高超声速飞行器非均匀等离子体电磁散射特性模拟测量研究. 利用弹道靶设备发射高超声速类HTV2模型形成模拟的超高速复杂外形目标, 弹道靶高精度阴影成像系统和雷达测量系统分别测量高超声速类HTV2模型姿态、全目标C波段/X波段电磁散射特性, 获得了不同实验条件下模型全目标雷达散射截面积(RCS)等实验数据. 研究结果表明: 在不同实验状态下, 包覆等离子体鞘套的高超声速类HTV2模型同一测量波段的RCS差别超过1个数量级, 模型姿态角对包覆等离子体鞘套的高超声速类HTV2模型RCS影响较大, 最大相差1个多数量级; 在给定的实验条件下, 模型尾迹C波段RCS远小于包覆等离子体鞘套的模型RCS, 模型尾迹X波段RCS显著增强; 高超声速类HTV2模型全目标C波段电磁散射能量主要分布在模型及其绕流区域, X波段电磁散射能量主要分布在模型及其绕流区域和等离子体尾迹区域. 根据弹道靶实验条件, 开展了包覆等离子体鞘套的高超声速类HTV2模型电磁散射特性数值仿真, 仿真结果与实验结果之间的最大误差小于4 dB, 验证了本文提出的非均匀等离子体包覆目标电磁散射特性建模方法的有效性.According to the requirements for target detection and recognition of hypervelocity vehicles in near space, the simulation and measurement of corresponding electromagnetic scattering characteristics of non-uniform plasma generated by hypervelocity targets are conducted. A numerical calculation method with dynamic plasma parameters is developed and hypervelocity HTV2-like models launched by the ballistic ranges are used to simulate complex shape target flying at a hypervelocity velocity. The high-precision shadow imaging systems and radar measurement systems of the ballistic range are used to measure the model postures, the electromagnetic scattering characteristics of the whole targets and their flow fields in both C band and X band. The experimental measurement results of the radar cross section (RCS) of the models and their flow fields under different experimental conditions are obtained. The results show that the numerical simulation methods of unsteady high-temperature ionized air flow can be used to simulate the unsteady thermal chemical flow fields around the head and body of the simplified hypervelocity HTV2-like flight models. The electromagnetic scattering characteristics of the models and their plasma sheath differ by more than one order of magnitude under different experimental conditions. The total RCS of the model’s wake in the C band is much smaller than that of the model, and the total RCS of the model’s wake in the X band is significantly enhanced. The attitude angles of the models have great influence on their electromagnetic scattering characteristics and their RCSs with different attitude angles can differ by one order of magnitude. The electromagnetic scattering energy of the model in the C band is distributed mainly around the targets and their flow fields surrounding them. The X band electromagnetic scattering energy of the model is distributed mainly in the regions around the targets, surrounding flow fields and the wake flow fields. According to the experimental conditions of the ballistic range, the numerical simulation analyses of the electromagnetic scattering characteristics of the models and flow fields around them are carried out, and the maximum error between simulation and experimental results is less than 4 dB, verifying the effectiveness of the modeling methods of simulating electromagnetic scattering characteristics of non-uniform plasma coated targets.
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Keywords:
- hypervelocity /
- model /
- plasma sheath /
- ballistic range
[1] Akey N D, Cross A E 1970 NASA-TN-D-5615 [1970-02-01]
[2] Dirsa E F 1960 Pro. IRE 48 703Google Scholar
[3] Golden K E, Pridmore D C, Stewart G E 1970 NASA 19710011626 (Washington: NASA LANGLEY Research Center)
[4] Wood G E, Asmar S W, Rebold T A 1997 TDA Progress Report 42 131
[5] Bachynski M P, Gibbs B W 1970 NASA 19710011649 (Washington: NASA LANGLEY Research Center)
[6] Sotnikov V L, Leboeuf J N, Mudaliar S 2010 IEEE Trans. Plasma Sci. 38 2208Google Scholar
[7] Usui H, Yamashita F, Matsumoto H 1999 Adv. Space Res. 24 1069Google Scholar
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Zhou C, Zhang X K, Zhang C X, Wu G C 2014 Modern Radar 36 83Google Scholar
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Wu W, Liu F, Zhong J L, Wang G H 2019 Chin. J. Radio. Sci. 34 610
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[16] Sun H Y, Wang J J, Han Y P, Cui Z W, Sun P, Shi X W, Zhao W J 2018 Int. J. Antennas Propag. 1 14
[17] 孙浩宇 2018 博士学位论文 (西安: 西安电子科技大学)
Sun H Y 2018 Ph. D. Dissertation (Xi’an: Xidian University) (in Chinese)
[18] 艾夏 2013 博士学位论文 (西安: 西安电子科技大学)
Ai X 2013 Ph. D. Dissertation (Xi’an: Xidian University) (in Chinese)
[19] 陈安涛 2019 博士学位论文 (西安: 西安电子科技大学)
Chen A T 2019 Ph. D. Dissertation (Xi’an: Xidian University) (in Chinese)
[20] 葛德彪, 闫玉波 2005 电磁波时域有限差分方法 (西安: 西安电子科技大学出版社) 第88—89页
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Chen W, Guo L X, Li J T, Dan L 2017 Acta Phys. Sin. 66 084102Google Scholar
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表 1 弹道靶高超声速球模型全目标RCS实验测量结果与数值计算结果对比
Table 1. Comparison between measurement and numerical results of the RCS of the ball models flying at hypervelocity.
实验状态 球模型及其等离子体鞘套套RCS/dBsm 尾迹RCS/dBsm 压力/kPa 速度/(km·s–1) 测量实验值 计算结果 实验测量值 计算结果 4.2 5.0 –31.40 –31.31 –52.10 –50.63 表 2 高超声速类HTV2模型C波段全目标RCS实验测量结果
Table 2. Measurement results of the C band full target RCS of the simplified HTV2 models flying at hypervelocity.
实验状态 模型姿态 高超声速类HTV2模型全目标RCS实测结果/dBsm 速度/(km·s–1) 压力/kPa 俯仰角
/(°)偏航角
/(°)滚转角
/(°)模型全目标
总RCS本体及绕流场RCS 尾迹RCS 5.0 7.6 22.43 5.18 103.65 5.91 5.90 –18.83 5.0 8.8 –1.85 14.79 –107.27 –4.19 –4.27 –21.57 5.0 10.4 –7.15 –2.10 69.40 –2.61 –2.72 –18.75 5.0 15.3 6.02 –10.1 –109.07 1.90 1.87 –19.79 表 3 高超声速类HTV2模型X波段全目标RCS实验测量结果
Table 3. Measurement results of the X band full target RCS of the simplified HTV2 models flying at hypervelocity.
实验状态 模型姿态 高超声速类HTV2模型全目标RCS
实测结果/dBsm速度
/(km·s–1)压力
/kPa俯仰角/(°) 偏航角
/(°)滚转角
/(°)模型全目标
总RCS本体及绕流场RCS 尾迹RCS 4.0 8.5 –17.00 23.00 6.80 –8.75 –8.76 –35.56 5.0 6.6 7.50 –11.00 108.28 1.05 1.05 –30.70 5.0 8.2 18.93 17.11 109.95 –2.92 –3.44 –12.43 5.0 11.6 4.03 –3.25 107.73 –3.63 –3.94 –15.23 5.0 14.8 –7.00 9.10 70.93 –5.99 –9.36 –8.68 表 4 高超声速类HTV2模型不同波段RCS的FDTD方法数值模拟结果与弹道靶实验测量结果的对比
Table 4. Various bands RCS comparisons between FDTD simulations and experiment results of the simplified HTV2 models flying at hypervelocity.
测量波段 实验状态 姿态角/(°) 模型及等离子体鞘套总RCS 压力
/kPa速度/(km·s–1) 俯仰角 偏航角 滚转角 测量/dBsm 计算/dBsm 误差/dB X 8.2 5.0 18.93 17.11 109.95 –3.30 –1.51 1.79 C 10.4 5.0 –7.15 –2.10 69.4 0.73 3.14 2.41 X 11.6 5.0 4.03 –3.25 107.73 –3.94 –5.20 1.26 X 14.8 5.0 –7.00 9.10 70.93 –9.26 –6.01 3.35 -
[1] Akey N D, Cross A E 1970 NASA-TN-D-5615 [1970-02-01]
[2] Dirsa E F 1960 Pro. IRE 48 703Google Scholar
[3] Golden K E, Pridmore D C, Stewart G E 1970 NASA 19710011626 (Washington: NASA LANGLEY Research Center)
[4] Wood G E, Asmar S W, Rebold T A 1997 TDA Progress Report 42 131
[5] Bachynski M P, Gibbs B W 1970 NASA 19710011649 (Washington: NASA LANGLEY Research Center)
[6] Sotnikov V L, Leboeuf J N, Mudaliar S 2010 IEEE Trans. Plasma Sci. 38 2208Google Scholar
[7] Usui H, Yamashita F, Matsumoto H 1999 Adv. Space Res. 24 1069Google Scholar
[8] Mather D E, Pasqual J M, Sillence J P, Lewis P 2005 AIAA/CIRA 13th International Space Planes and Hypersonics Systems and Technology Capua, Italy, May 16–20, 2005 p3443
[9] 周超, 张小宽, 张晨新, 吴国成 2014 现代雷达 36 83Google Scholar
Zhou C, Zhang X K, Zhang C X, Wu G C 2014 Modern Radar 36 83Google Scholar
[10] 吴巍, 刘方, 钟建林, 王国宏 2019 电波科学学报 34 610
Wu W, Liu F, Zhong J L, Wang G H 2019 Chin. J. Radio. Sci. 34 610
[11] 金铭, 韦笑, 吴洋, 张羽淮, 余西龙 2015 物理学报 64 205205Google Scholar
Jin M, Wei X, Wu Y, Zhang Y H, Yu X L 2015 Acta Phys. Sin. 64 205205Google Scholar
[12] 马平, 石安华, 杨益兼, 于哲峰, 黄洁 2015 强激光与粒子束 27 073201Google Scholar
Ma P, Shi A H, Yang Y J, Yu Z F, Huang J 2015 High Power Laser Part. Beams 27 073201Google Scholar
[13] 马平, 石安华, 杨益兼, 于哲峰, 梁世昌, 黄洁 2017 物理学报 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
[14] 邾继贵, 于之靖 2012 视觉测量原理与方法 (北京: 机械工业出版社) 第4678页
Zhu J G, Yu Z J 2012 Principles and Methods of Visual Measurements (Beijing: China Machine Press) pp46–78 (in Chinese)
[15] Sun H Y, Cui Z W, Wang J J, Han Y P, Shi P 2018 Phys. Plasmas 25 063514Google Scholar
[16] Sun H Y, Wang J J, Han Y P, Cui Z W, Sun P, Shi X W, Zhao W J 2018 Int. J. Antennas Propag. 1 14
[17] 孙浩宇 2018 博士学位论文 (西安: 西安电子科技大学)
Sun H Y 2018 Ph. D. Dissertation (Xi’an: Xidian University) (in Chinese)
[18] 艾夏 2013 博士学位论文 (西安: 西安电子科技大学)
Ai X 2013 Ph. D. Dissertation (Xi’an: Xidian University) (in Chinese)
[19] 陈安涛 2019 博士学位论文 (西安: 西安电子科技大学)
Chen A T 2019 Ph. D. Dissertation (Xi’an: Xidian University) (in Chinese)
[20] 葛德彪, 闫玉波 2005 电磁波时域有限差分方法 (西安: 西安电子科技大学出版社) 第88—89页
Ge D B, Yan Y B 2005 Finite-Difference Time-Domain Method for Electromagnetic Waves (Xi’an: Xidian University Press) pp88–89 (in Chinese)
[21] Ai X, Han Y, Li C Y, Shi X W 2011 Prog. Electromagn. Res. Lett. 22 83Google Scholar
[22] Ai X, Han Y, Chen Z, Shi X W 2011 Prog. Electromagn. Res. M. 18 143Google Scholar
[23] Ai X, Tian Y, Han Y P, Shi X W, Li W T 2013 J. Quant. Spectrosc. Radiat Transfer 124 28Google Scholar
[24] 陈伟, 郭立新, 李江挺, 淡荔 2017 物理学报 66 084102Google Scholar
Chen W, Guo L X, Li J T, Dan L 2017 Acta Phys. Sin. 66 084102Google Scholar
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