T-ray Photoconductive Antenna Design for Biomedical Imaging Applications

2023 International Microwave and Antenna Symposium (IMAS) Pub Date : 2023-02-07 DOI:10.1109/IMAS55807.2023.10066897

Ruobin Han, Abdoalbaset Abohmra, Shohreh Nourinovin, H. Abbas, Joao Ponciano, Lingfeng Shi, A. Alomainy, M. Imran, Q. Abbasi

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Abstract

Photoconductive antennas are promising sources of terahertz (THz) radiation, which is frequently used to investigate and analyze biological organisms. These compact antennas make it possible to generate ultra-broadband pulses and continuously tunable THz transmissions at room temperature without the need for high-power laser sources. Here, a high efficiency spiral THz photoconductive antenna (PCA) is proposed. The design consists of a gallium arsenide (GaAs) substrate and a silicon (Si) hyper hemispherical lens. The proposed design has a radiation efficiency of up to 92.4% between 2.5 and 3.4 THz, with a directivity up to 17.6 dBi. With several current PCA designs as references, comparisons and analyses are made, indicating that the proposed work shows higher efficiency and radiation directivity at a wider band. The design of electrodes and hyper hemispherical lens are demonstrated in the paper. Simulations of contrast designs are shown as well, illustrating a 25%-40% efficiency and 12.8 dB gain increase by this design. Due to its performance and small structure, this antenna is ideal for T-ray medical imaging.

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生物医学成像应用的t射线光导天线设计

光导天线是很有前途的太赫兹(THz)辐射源，经常用于研究和分析生物有机体。这些紧凑的天线使得在室温下产生超宽带脉冲和连续可调谐太赫兹传输成为可能，而不需要高功率激光源。本文提出了一种高效的螺旋太赫兹光导天线(PCA)。该设计由砷化镓(GaAs)衬底和硅(Si)超半球面透镜组成。该设计在2.5 ~ 3.4太赫兹范围内的辐射效率高达92.4%，指向性高达17.6 dBi。对比分析了现有的几种主成分分析方法，结果表明该方法具有更高的效率和更宽波段的辐射指向性。对电极和超半球面透镜的设计进行了论证。对比设计的仿真结果表明，该设计可提高25%-40%的效率和12.8 dB的增益。由于它的性能和小结构，这种天线是理想的t射线医学成像。

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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2023 International Microwave and Antenna Symposium (IMAS)

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