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用于毫米波的超表面吸收器:一种用于增强宽带双端口MIMO天线隔离度的深度学习优化方法。

Metasurface absorber for millimeter waves: a deep learning-optimized approach for enhancing the isolation of wideband dual-port MIMO antennas.

作者信息

Narayanaswamy Nagesh Kallollu, Satheesha T Y, Alzahrani Yazeed, Pandey Ashish, Dwivedi Ajay Kumar, Singh Vivek, Tolani Manoj

机构信息

Department of Electronics and Communication Engineering, Nagarjuna College of Engineering and Technology, Bengaluru, India.

School of Computer Science Engineering, REVA University, Bengaluru, Karnataka, India.

出版信息

Sci Rep. 2024 Dec 4;14(1):30199. doi: 10.1038/s41598-024-81854-5.

DOI:10.1038/s41598-024-81854-5
PMID:39632997
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11618610/
Abstract

In this communication, the concept of metasurface absorber is utilized to enhance the isolation in the dual port multiple-input multiple-output (MIMO) antenna specially designed for a wideband millimeter wave operation. The frequency of operation of the designed module is 32.5-42.5 GHz with sufficient gain attributes. The designed metasurface array consists of two circular rings on two different layers. The concept of deep learning is utilized to optimize the dimensional configuration of the metasurface to achieve the maximum absorption of electromagnetic waves in the band of interest. The suppression of mutual coupling by double-ring metasurface is analyzed with the help of the wave theory concept. In contrast to previous decoupling methods using metasurfaces, the suggested metasurface is intended to be in the same plane as the array. The findings demonstrate the capability of effectively separating antenna elements in wideband MIMO antenna without compromising the geometrical complexity. Diversity metrics such as envelope correlation coefficient (ECC), mean effective gain (MEG), channel capacity loss (CCL), and total active reflection coefficient (TARC) for the proposed frequency range are also used to evaluate the performance of the constructed MIMO antenna. The wideband characteristics with a compact configuration make the design MIMO module a suitable candidate for mm-wave applications. The congruence between simulation and measurement confirms the validity of the suggested design.

摘要

在本通信中,超表面吸收器的概念被用于增强专门为宽带毫米波操作设计的双端口多输入多输出(MIMO)天线的隔离度。所设计模块的工作频率为32.5 - 42.5 GHz,具有足够的增益特性。所设计的超表面阵列由两层上的两个圆环组成。利用深度学习的概念来优化超表面的尺寸配置,以在感兴趣的频段实现电磁波的最大吸收。借助波动理论概念分析了双环超表面对互耦的抑制作用。与先前使用超表面的去耦方法不同,所建议的超表面与阵列位于同一平面内。研究结果表明,该超表面能够在不增加几何复杂度的情况下,有效分离宽带MIMO天线中的天线单元。针对所提出的频率范围,还使用了诸如包络相关系数(ECC)、平均有效增益(MEG)、信道容量损失(CCL)和总有源反射系数(TARC)等分集指标来评估所构建的MIMO天线的性能。具有紧凑结构的宽带特性使所设计的MIMO模块成为毫米波应用的合适候选方案。仿真与测量结果的一致性证实了所建议设计的有效性。

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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/fcb3/11618610/1bdd2dad460e/41598_2024_81854_Fig7_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/fcb3/11618610/328eab463e6a/41598_2024_81854_Fig8_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/fcb3/11618610/fbbd3dd1daf1/41598_2024_81854_Fig9_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/fcb3/11618610/a327238a86b6/41598_2024_81854_Fig10_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/fcb3/11618610/d48f4393c4b4/41598_2024_81854_Fig11_HTML.jpg
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3
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5
Fast optimization method of designing a wideband metasurface without using the Pancharatnam-Berry phase.一种无需使用庞加莱-贝里相位设计宽带超表面的快速优化方法。
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6
Broadband metasurfaces with simultaneous control of phase and amplitude.宽带超表面同时控制相位和幅度。
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7
Flat metasurfaces to focus electromagnetic waves in reflection geometry.平面亚波长结构反射聚焦电磁波。
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8
Ultra-small single-negative electric metamaterials for electromagnetic coupling reduction of microstrip antenna array.用于降低微带天线阵列电磁耦合的超小型单负电磁超材料
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9
Light propagation with phase discontinuities: generalized laws of reflection and refraction.具有相位不连续性的光传播:反射和折射的广义定律。
Science. 2011 Oct 21;334(6054):333-7. doi: 10.1126/science.1210713. Epub 2011 Sep 1.