摘要
针对采用平均后向散射系数进行对地空炸毫米波引信回波仿真时,因照射区域内入射角度散布较大造成仿真精度不足的问题,对复杂地物背景后向散射特性测试的远场条件进行了讨论,修正了复杂地物背景毫米波近场测试远场条件表达式,提出一种针对引信对地探测的复杂地物背景角域后向散射分布建模方法,构建基于实测数据优化的土耕地、水泥地等背景角域后向散射场,分析其对引信探测响应回波的影响。仿真结果表明,接近垂直入射情况下与传统乌拉比模型比较一致性较好,接近水平入射情况下比乌拉比模型后向散射系数小2~4 dB。利用该引信回波算法提高了毫米波引信探测仿真精度,可为对地空炸毫米波引信探测器设计提供数据支撑。
In order to solve the problem of insufficient simulation accuracy caused by the large scattering angle of the incident angle in the irradiation area when using the average backscattering coefficient to simulation the echo of enemy air blast millimeter wave fuzes,the far-field conditions for testing the backscattering characteristics of complex ground backgrounds were discussed,and the far-field condition expression for millimeter wave near-field tasting of complex ground backgrounds were modified.Then,a complex ground background angle domain backscatter distribution model for ground fuze detection was proposed.Based on the measured data,the optimized backscattering field in the soil cultivated land,cement land and so on were constructed,and its influence on the response echo of fuze detection was analyzed.The simulation results showed that the proposed model had high consistency with the traditional Ulaby model in the case of near vertical incidence.The backscatter coefficient was 2~4 dB lower than that of the Ulaby model under near horizontal incidence conditions.The simulation accuracy of millimeter wave fuze detection was improved by using the fuze echo algorithm of this model,which could provide data support for the design of millimeter wave fuze detector for ground-to-air explosion.
作者
田博
何海军
钟海超
李铁
TIAN Bo;HE Haijuni;ZHONG Haichao;LI Tie(Science and Technology on Electromechanical Dynamic Control Laboratory,Xi'an 710065,China;No.212 Institute of China Ordnance Industry Corporation,Xi'an 710065,China)
出处
《探测与控制学报》
CSCD
北大核心
2024年第4期26-31,共6页
Journal of Detection & Control
关键词
地物后向散射
对地空炸引信
角域后向散射系数
散射分布函数
仿真
backscattering of ground
ground-to-air explosion fuze
angular domain backscatter coefficient
scattering distribution function
simulation
