Li Ying, Huang Peilin, Wu Zheet al. Model of radar network detection based on average RCS value of different angle territory[J]. Journal of Beijing University of Aeronautics and Astronautics, 2008, 34(06): 627-629. (in Chinese)
Citation: Li Ying, Huang Peilin, Wu Zheet al. Model of radar network detection based on average RCS value of different angle territory[J]. Journal of Beijing University of Aeronautics and Astronautics, 2008, 34(06): 627-629. (in Chinese)

Model of radar network detection based on average RCS value of different angle territory

  • Received Date: 18 May 2007
  • Publish Date: 30 Jun 2008
  • There are great differences among the target-s radar cross section values in its different angle territory. A new model about mono radar detect probability and radar network comprehensive detect probability was presented. The model was based on the target-s average radar cross section value in its different angle territory. It adopted two different plans in the computer simulation platform: taking the target-s single average radar cross section value; taking the target-s different average radar cross section in its different angle territory, according to the angle of radar refers to the target. There are differences between the two plans- detect probability results, which prove the model-s rationality. The detect model fits the actual detect situation that radar will detect different radar cross section values from different detect angles. The detect probability result is more accurate which comes from the plan that taking the target-s different average radar cross section in its different angle territory.

     

  • [1] 张考,马东立.军用飞机生存力与隐身设计[M].北京:国防工业出版社,2002:196-199 Zhang Kao,Ma Dongli. Military aircraft survivability and stealth design[M].Beijing:Defense Industry Press, 2002:196-199(in Chinese) [2] 丁鹭飞,耿富录.雷达原理[M].西安:西安电子科技大学出版社,2002:128-132 Ding Lufei,Geng Fulu.Radar principle[M].Xi’an;XiDian University Press, 2002:128-132(in Chinese) [3] 郭正新,江晶.一种不同距离的雷达探测概率计算模型[J].空军雷达学院学报,2003,17(4):7-8 Guo Zhengxin,Jiang Jing. Computation model of radar detection probability with various distance[J]. Journal of Air Force Radar Academy,2003,17(4):7-8(in Chinese) [4] 李光明,唐业敏,蒋苏蓉.雷达网反隐身性能评估[J].现代雷达,2006,28(1):23-25 Li Guangming,Tang Yemin,Jiang Surong. Performance evaluation of radar network for counterchecking stealth aircraft comprehensive detecting probability of radar network[J].Modern Radar, 2006,28(1):23-25(in Chinese) [5] 王中许,李银伢,张学彪.雷达组网仿真研究与实现[J].南京理工大学学报,2006,30(3):293-294 Wang Zhongxu,Li Yinya,Zhang Xuebiao.Research and realization of multi-radar netting simulation[J].Journal of Nanjing University of Science and Technology, 2006,30(3):293-294(in Chinese)
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