面向 5G/IoT 应用的高性能 MTM 启发式双端口 MIMO 天线结构

Samia Hamdan, E. Hamad, Hesham A. Mohamed, Sherif A. Khaleel
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摘要

摘要 本研究深入探讨了一种双端口多输入多输出(MIMO)天线系统,该系统专为 5G 在 28 GHz 频率下运行而量身定制。所提议的天线是在相对介电常数为 2.2、总尺寸为 20×12×0.508 mm3 的罗杰斯 (RT5880) 衬底上贴片的。利用 H 型超材料结构细化了辐射贴片之间的相互关系,从而将隔离度降低到 -55 dB。它采用了具有吸引力的 MIMO 配置,将包络相关系数(ECC)降至约 0.00062,信道容量损失(CCL)降至约 0.006 比特/秒/赫兹,同时将增益放大至约 9.39 dBi,分集增益(DG)放大至约 9.995。此外,该天线体积小巧,辐射模式稳定。MIMO 天线的仿真由 CST 微波工作室执行,随后通过高级设计系统 (ADS) 验证等效电路模型,然后使用矢量网络分析仪进行测量。对测量和模拟结果之间的差异进行了分析,观察到的变化归因于电缆损耗和制造公差。尽管存在这些挑战,但通过与先前研究的全面比较,我们发现了拟议设计的显著优势,并将其定位为 5G 应用的一个引人注目的解决方案。
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High-performance MTM inspired two-port MIMO antenna structure for 5G/IoT applications
Abstract This study thoroughly investigates a two-port multiple-input multiple-output (MIMO) antenna system tailored for 5G operation at 28 GHz. The proposed antenna is patched on a Rogers (RT5880) substrate with a relative permittivity of 2.2 and total size of 20×12×0.508 mm3. The mutual relationship between the radiating patches is refined using an H-shaped metamaterial structure to reduce the isolation to –55 dB. A MIMO configuration with attractive features is employed to reduce the envelope correlation coefficient (ECC) to about 0.00062 and the channel capacity loss (CCL) to about 0.006 bits/sec/Hz, while magnify the gain to about 9.39 dBi and the diversity gain (DG) to about 9.995. Additionally, it boasts a compact size with stable radiation pattern. The simulations of the MIMO antenna are executed using CST microwave studio, subsequently validated with Advanced Design System (ADS) for an equivalent circuit model, then measured using Vector Network Analyzer. Discrepancies between measured and simulated results were analyzed, with observed variations attributed to cable losses and manufacturing tolerances. Despite these challenges, a comprehensive comparison with prior research highlights the notable advantages of the proposed design, positioning it as a compelling solution for 5G applications.
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