利用平面相控面减小RCS和控制波

2017 IEEE International Conference on Antenna Innovations & Modern Technologies for Ground, Aircraft and Satellite Applications (iAIM) Pub Date : 2017-11-01 DOI:10.1109/IAIM.2017.8402581

Rajanikanta Swain, R. K. Mishra

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引用次数: 0

摘要

本文提出了一种抑制入射波反射或减小雷达截面(RCS)的方案。优化了一种非谐振改性耶路撒冷型元原子，使其在多个介质支撑下获得线性相位响应。线性相位排列的近场模拟结果表明，相控粒子的随机分布使入射波在三个频率样品(9.5GHz、10GHz和10.5GHz)上产生扩散散射。与金属平面板的情况相比，线性相控元原子的模拟双基地RCS模式显示出对最大RCS方向的强大操纵。在随机相位表面的情况下，我们证明RCS减少了大约15dBsM。由于有效的反射抑制和低成本的平面几何结构，我们的工作为x波段隐身技术提供了新的途径。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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RCS reduction and wave manipulation using planar phased surface

In this paper a scheme to suppress reflection of incident wave or reduction of radar cross section (RCS) is proposed. A non-resonant modified Jerusalem type meta-atom is optimized to obtain linear phase response with several dielectric support. Simulated near-field results of a linear arrangement of phase show powerful beam steering capabilities while the random distribution of phased particles produces a diffused scattering of incident wave at three frequency samples (9.5GHz, 10GHz, and 10.5GHz). Simulated bistatic RCS patterns of linearly phased meta-atoms show powerful manipulation of the direction of maximum RCS when compared to the case of the metallic plane plate. In the case of randomly phased-surface, we demonstrated approximately 15dBsM reduction of RCS. Due to Efficient suppression of reflection and low-cost planar geometry, our work enables novel route for x-band stealth technology.

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来源期刊

2017 IEEE International Conference on Antenna Innovations & Modern Technologies for Ground, Aircraft and Satellite Applications (iAIM)

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