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Paper detail

A metasurface composed of 3-bit coding linear polarization conversion elements and its application to RCS reduction of patch antenna

In this paper, a low radar cross section (RCS) patch antenna based on the 3-bit metasurface composed of linear polarization conversion elements is designed. At first, 3-bit coding metamaterials are constructed by a sequence of eight coded unit cells, which have a similar cross-polarized reflected amplitude response and gradient reflected phase responses covering 0~2π, respectively. Equivalent circuit models (ECMs) of these unit cells are created to describe their electrical behavior for the two linear incident polarizations at the same time. Then, a patch antenna is integrated on the 3-bit metasurface, of which the elements are placed with a 2-dimensional linear coding sequence. The metal square ring is set around the patch antenna to protect it from the disturbance of metasurface. Both the simulation and experiment results demonstrate that the designed metasurface can primarily reduce the antenna RCS at a broadband, while the antenna performances are not degraded significantly.

preprint2020arXivOpen access
Xiangkun KongQi WangShunliu JiangLingqi KongYuan JingXiangxi YanXing Zhao
physics.app-ph
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Xiangkun KongQi WangShunliu JiangLingqi KongYuan JingXiangxi YanXing Zhao

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