A New Modification Approach to Enhance the EM Performance of an S-Band Patch Antenna for Nanosatellite Application

2022 IEEE Asia-Pacific Conference on Geoscience, Electronics and Remote Sensing Technology (AGERS) Pub Date : 2022-12-21 DOI:10.1109/AGERS56232.2022.10093609

Marc Jafet C. Barbosa, Princess Lheakyrie R. Casilao, Raymond Aries O. Fernando, Ron Michael M. Beato, Mary Joy V. De La Rosa, Raynell A. Inojosa

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Abstract

An antenna design capable of providing reliable communication link has been a great research interest in nanosatellite applications. Hence, this study aimed to modify a design of a patch antenna for nanosatellite application operated in S-band, providing an improved antenna performance. The design and electromagnetic (EM) simulation of the antenna are carried out using the Ansys® High Frequency Structure Simulator (HFSS). With regard to the improvement of antenna performance, a reference antenna design was adopted and modified by incorporating various modification approach. The proposed patch antenna is designed on an RT Duroid 5870 dielectric substrate and can resonate well at frequencies 2.330 GHz and 2.585 GHz having minimum return loss of below −20 dB, VSWR of less than 1.7, and a maximum gain of around 7 dBi, respectively. Through the aid of MATLAB® Satellite Communication Toolbox, this study was able to test and evaluate the antenna design performance in terms of link margin and free space path loss proving that the proposed antenna provides better performance.

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一种改进纳米卫星s波段贴片天线电磁性能的新方法

能够提供可靠通信链路的天线设计一直是纳米卫星应用领域的研究热点。因此，本研究旨在改进s波段纳米卫星应用的贴片天线设计，以提高天线性能。利用Ansys®高频结构模拟器(HFSS)对天线进行了设计和电磁仿真。在天线性能改进方面，采用参考天线设计，并结合多种改进方法进行改进。该贴片天线设计在RT Duroid 5870介质衬底上，在2.330 GHz和2.585 GHz频率下具有良好的谐振性能，最小回波损耗小于- 20 dB，驻波比小于1.7，最大增益约为7 dBi。借助MATLAB®卫星通信工具箱，本研究能够从链路裕度和自由空间路径损耗方面对天线设计性能进行测试和评估，证明所提出的天线具有更好的性能。

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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2022 IEEE Asia-Pacific Conference on Geoscience, Electronics and Remote Sensing Technology (AGERS)

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