GPS微带天线的设计与制作

2020 International Conference on Computer Science and Software Engineering (CSASE) Pub Date : 2020-04-01 DOI:10.1109/CSASE48920.2020.9142081

S. H. Fadhil, R. H. Thaher

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引用次数: 1

摘要

提出了一种新的全球定位系统(GPS)微带贴片天线设计方案。所建议的模型在1处运行。谐振频率为575GHz，增益4.974 dBi，轴比2.956,S11 = - 35.554 db。分析了回波损耗、电压驻波比和输入阻抗等参数。GPS天线单元采用矩形贴片和两个角截断槽来实现。在贴片和接地面上增加许多插槽，以获得回波损耗最佳值时的谐振频率(即S11 $\leq$ -10dB)。利用矢量网络分析仪(VNA)建立了该模型并进行了实际测试。在相对介电常数$\varepsilon \mathrm{r}=4.3$和损耗正切$\tan\delta=0.025$的衬底上制作了该贴片天线，并进行了实际测试。结果表明，仿真结果与实际结果吻合较好。这种细微的差别是由于制造错误造成的。

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Design and Fabrication of GPS Microstrip Antenna

A new design of microstrip patch antenna for Global Positioning System (GPS) is presented. The proposed model operates at 1. 575GHz resonant frequency and has a gain 4.974 dBi and axial ratio 2.956 with S11 = – 35.S54dB. Various parameters such as return loss, Voltage Standing Wave Ratio (VSWR) and input impedance has been analyzed. The GPS antenna elements is achieved by using rectangular patch with two corners truncated slots. Many slots are added to the patch and ground plane to obtain the resonant frequency at best value of return loss (i.e. S11 $\leq$-10dB). The model was fabricated and tested practically using Vector Network Analyzer (VNA). The proposed patch antenna was manufactured on substrate with relative dielectric constant $\varepsilon \mathrm{r}=4.3$ and loss tangent $\tan\delta=0.025$ and tested practically. It was noted that there is a reasonable agreement between the simulation results and practical results. The slight difference is attributed to manufacturing errors.

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2020 International Conference on Computer Science and Software Engineering (CSASE)

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