ELECTROMAGNETISM, OPTICS, ACOUSTICS, HEAT TRANSFER, CLASSICAL MECHANICS, AND FLUID DYNAMICS |
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A hybrid method of solving near-zone composite eletromagnetic scattering from targets and underlying rough surface |
Xi-Min Li(李西敏)1, Jing-Jing Li(李晶晶)1, Qian Gao(高乾)2, Peng-Cheng Gao(高鹏程)3 |
1 Air Force Engineering University, Xi'an 710051, China; 2 Air Force Communication NCO Academy, Dalian 116199, China; 3 Science and Technology on Electromagnetic Scattering Laboratory, Shanghai 200438, China |
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Abstract For composite electromagnetic (EM) scattering from rough surface and target above it in near-field condition, modified shooting and bouncing ray (SBR) method and integral equation method (IEM), which are analytic methods combined with two-scale model for rough surface, are proposed to solve the composite near-field scattering problems. And the modified method is verified in effectiveness and accuracy by comparing the simulation results with measured results. Finally, the composite near-fielding scattering characteristics of a slanted plane and rough water surface below are obtained by using the proposed methods, and the dynamic tendency of composite scattering characteristics versus near-fielding distance is analyzed, which may have practical contribution to engineering programs in need of radar targets near-field characteristics under extra-low-altitude conditions.
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Received: 25 July 2019
Revised: 27 October 2019
Accepted manuscript online:
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PACS:
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42.68.Mj
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(Scattering, polarization)
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42.68.Ay
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(Propagation, transmission, attenuation, and radiative transfer)
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42.25.Bs
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(Wave propagation, transmission and absorption)
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42.15.Dp
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(Wave fronts and ray tracing)
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Fund: Project supported by the National Natural Science Foundation of China (Grant No. 61372033). |
Corresponding Authors:
Xi-Min Li
E-mail: bigboy11272000@126.com
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Cite this article:
Xi-Min Li(李西敏), Jing-Jing Li(李晶晶), Qian Gao(高乾), Peng-Cheng Gao(高鹏程) A hybrid method of solving near-zone composite eletromagnetic scattering from targets and underlying rough surface 2020 Chin. Phys. B 29 024202
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