Radiation Performances of Side Reduced Terahertz Dielectric Silicon Lens Antenna

2020 12th International Conference on Information Technology and Electrical Engineering (ICITEE) Pub Date : 2020-10-06 DOI:10.1109/ICITEE49829.2020.9271706

C. Apriono, Farida Ulfah

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引用次数: 1

Abstract

Although the use of a dielectric lens has shown the gain improvement, the hemispherical shape gives other considerations, which are an effective function of the whole lens, and occupied size just for one sensor. This research proposes a size reduction technique to reduce lens size. The reduced size consideration is necessary to provide an as small as possible sensor of a planar crossed bowtie feeding antenna at a working frequency of 1 THz that radiates THz wave radiation and then collimated by a hemispherical dielectric silicon lens. The initially considered lens diameter and the extended dielectric thickness are 3000 µm and 1000 µm, respectively. This research conducts those investigations by using CST Microwave Studio. The results show that reduced performances of gain and radiation efficiency. However, the gain decreasing slowly at the beginning of the substrate reduction means that the expected gain remains to obtain. The gain still can be achieved at around 30 dB when the extension is about 1000 µm. This technique offers more suppressed side lobe levels and reduced the volume use of dielectric materials. The research can contribute to farther research to develop a compact THz wave sensor device based on a planar antenna and a quasi-optical dielectric lens.

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侧减太赫兹介质硅透镜天线的辐射性能

虽然使用介质透镜可以提高增益，但半球形透镜还需要考虑其他因素，即整个透镜的有效功能，以及仅用于一个传感器所占用的尺寸。本研究提出了一种缩小透镜尺寸的技术。在工作频率为 1 太赫兹的平面交叉弓形馈电天线上，辐射出太赫兹波，然后由半球形介电硅透镜准直，为了提供尽可能小的传感器，缩小尺寸是必要的。最初考虑的透镜直径和扩展介质厚度分别为 3000 微米和 1000 微米。本研究使用 CST Microwave Studio 进行了这些研究。结果表明，增益和辐射效率都有所降低。然而，增益在基底减薄初期缓慢下降，这意味着仍可获得预期增益。当延伸约 1000 微米时，增益仍可达到 30 dB 左右。这种技术能更有效地抑制侧叶电平，并减少电介质材料的使用量。这项研究有助于进一步开发基于平面天线和准光学介质透镜的紧凑型太赫兹波传感器设备。

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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2020 12th International Conference on Information Technology and Electrical Engineering (ICITEE)

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