超材料结构对用于 LTE/WIFI / 癌症诊断的印刷天线的影响

Journal of Advanced Research in Applied Sciences and Engineering Technology Pub Date : 2024-06-04 DOI:10.37934/araset.46.1.237249

Fatma Taher, A. M. M. A. Allam, Ahmed F. Miligy, Mohamed A. Mohamed, Mohamed Fathy Abo Sree, Sara Yehia Abdel Fatah

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引用次数: 0

摘要

本文将探讨 METAMORAL ULC 对 LTE / Wi-Fi 印刷天线性能的影响。我们将研究两种不同的天线版本。一个版本具有 METAMORAL 地层，是传统的天线。另一个版本将在改变后的天线上附加 METAMORAL 负载。天线中的超材料地层将支持具有 MTM 结构的单元单元，我们将研究 MTM 结构如何影响天线的性能。我们将使用基板厚度为 1.575 毫米、介电常数为 2.2 的 Roger 5880 来测试这两种版本的天线。天线的整体尺寸为 60×49×1.575mm，损耗正切为 0,0009。获得理想的电感器/电容器值后，我们就能为计划电路和传统电路创建等效电路。然后，我们将在 CST 微波工作室中模拟电路。路径波 ADS 模拟器将运行等效电路。天线由网络分析仪 Rode 制造和测量天线覆盖的频率范围是1.68 GHz 2.51 GHz 3.56 4.63 GHz 4.1 GHz 5.1 GHz 标准应用 2.58 dB/2.45 dB 模拟增益 2.22 dB/5.19 dB 观察增益两种模拟器的测量值和报价值之间具有极好的一致性模拟的特定吸收率在样品乳房幻影上 1g / 10g SAR 值必须介于 10g 欧盟限值和 1g 美国限值之间是否适合用于癌症诊断和检测？

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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Metamaterial Structure Effect on Printed Antenna for LTE/WIFI /Cancer Diagnosis

In this paper, we will look at the impact of METAMORAL ULC on the performance of LTE / Wi-Fi printed antennas. We will look at two different antenna versions. One version will have the METAMORAL ground layer and will be the traditional antenna. The other version will have a METAMORAL load attached to the altered antenna. The metamaterial ground layer in the antenna will support the unit cell with the MTM structure, and we will look at how the MTM structure affects the performance of the antenna. We will use Roger 5880 with a substrate thickness (1.575 mm) and Dielectric constant (2.2) to test both antenna versions. The antenna’s overall dimensions are 60×49×1.575mm and the loss tangent is 0,0009. Once we have the ideal inductor/capacitor values, we will be able to create equivalent circuits for our planned circuit as well as the conventional circuit. We will then simulate the circuit in CST microwave studio. The path wave ADS simulator runs the equivalent circuit. The antenna is manufactured and measured by Network Analyser Rode Frequency ranges covered by the antenna are: 1.68 GHz 2.51 GHz 3.56 4.63 GHz 4.1 GHz 5.1 GHz Standard applications 2.58 dB/2.45 dB simulated gain 2.22 dB/5.19 dB observed gain Excellent agreement between measured and quoted value from both simulators Particular rate of absorption simulated On a sample Breast Phantom 1g / 10g SAR value must fall between 10g EU limit and 1g US limit Is suitable for use in Cancer diagnosis and detection?

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来源期刊

Journal of Advanced Research in Applied Sciences and Engineering Technology

CiteScore

1.30

自引率

0.00%

发文量