Radiation performance and Specific Absorption Rate (SAR) analysis of a compact dual band balanced antenna

2015 IEEE International Conference on Electro/Information Technology (EIT) Pub Date : 2015-05-21 DOI:10.1109/EIT.2015.7293415

A. Iftikhar, M. Masud, M. N. Rafiq, S. Asif, B. Braaten, M. S. Khan

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引用次数: 3

Abstract

This paper presents a compact dual-band dipole antenna with meander line radiating elements. The proposed antenna has a balanced structure with dimensions of 35×6×1.52 mm3, and mounted on a 36.2 × 100 mm2 floating ground plane. The balanced operation of the design is validated by incorporating a differential feed in the software simulation and a 180 ° hybrid junction is used for measurement with the network analyzer to verify the balanced concept of the prototype. Simulated and measured results of the S-parameters along with the de-tuning of the antenna in the presence of the human body shows good agreement. Moreover the proposed design is used as an exposure source to the simulated human head model. The human head is modeled as six layers in the Electromagnetic (EM) software HFSS to study the interaction between the proposed balanced antenna and the human head model. The Electric field (E-field) distribution in the six layers of the human head model is shown to estimate the penetration of the field when the antenna is placed at a distance of 7 mm from the proposed design. Also Local Specific Absorption Rates (SARs) and average SARs simulation results at 3.78 GHz and 4.29 GHz are shown. The SARs analysis showed that in all the six layers of the human head model, local SAR values are greater in fat and Cerebrospinal fluid (CSF) for both the frequencies while the average SAR values are not very high.

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一种紧凑型双波段平衡天线的辐射性能和比吸收率分析

本文提出了一种具有弯曲线辐射元件的紧凑双频偶极子天线。该天线采用平衡结构，尺寸为35×6×1.52 mm3，安装在36.2 × 100 mm2的浮地平面上。通过在软件仿真中加入差分进给，验证了设计的平衡运行，并使用180°混合结与网络分析仪进行测量，以验证原型的平衡概念。在人体存在的情况下，对天线的s参数进行了仿真和实测，结果与实验结果吻合较好。此外，所提出的设计被用作模拟人头模型的暴露源。在电磁软件HFSS中对人体头部进行了六层建模，研究了所提出的平衡天线与人体头部模型之间的相互作用。当天线放置在距离所提出的设计7毫米的距离时，显示了人类头部模型六层中的电场(E-field)分布，以估计场的穿透。同时给出了3.78 GHz和4.29 GHz下的局部比吸收率(sar)和平均sar模拟结果。SAR分析表明，在人体头部模型的所有六层中，脂肪和脑脊液(CSF)的局部SAR值在两个频率下都较大，而平均SAR值不是很高。

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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来源期刊

2015 IEEE International Conference on Electro/Information Technology (EIT)

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