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PIER PIER B PIER C PIER M PIER Letters
2018-04-02
An 8 GHz Front-End Module with High-Performance T/R Switch and LNA
By
He Qi,

    Dr. He Qi

    Department of Electronics Engineering

    Shanghai Jiao Tong University

    China

    Homepage

Jun-Ping Geng,

    Dr. Jun-Ping Geng

    Dept. of Electronic Engineering

    Shanghai Jiao Tong University

    China

    Homepage

Weiren Zhu,

    Dr. Weiren Zhu

    Department of Electronics Engineering

    Shanghai Jiao Tong University

    China

    Homepage

Liang Liu,

    Dr. Liang Liu

    Department of Electronics Engineering

    Shanghai Jiao Tong University

    China

    Homepage

Ziheng Ding,

    Dr. Ziheng Ding

    Department of Electronics Engineering

    Shanghai Jiao Tong University

    China

    Homepage

Xianling Liang,

    Dr. Xianling Liang

    Department of Electronic Engineering

    Shanghai Jiao Tong University

    China

    Homepage

Tingting Fan,

    Dr. Tingting Fan

    Department of Electronics Engineering

    Shanghai Jiao Tong University

    China

    Homepage

Xiangzhong Fang,

    Dr. Xiangzhong Fang

    Department of Electronics Engineering

    Shanghai Jiao Tong University

    China

    Homepage

Rong-Hong Jin

    Dr. Rong-Hong Jin

    Dept. of electronic Engineering

    Shanghai Jiao Tong University

    China

    Homepage

Progress In Electromagnetics Research C, Vol. 82, 185-197, 2018
doi:10.2528/PIERC18011007 | Google Scholar

Abstract
A front-end module (FEM) consisting of a single-pole-double-throw (SPDT) switch and a low noise amplifier (LNA) with good performance is proposed. The SPDT switch is based on PIN diodes, which are mounted on impedance transforming lines parallelled to the main transmission lines with an asymmetric topology. This asymmetric topology is utilized to achieve low insertion loss and high transmit-to-receive isolation. The interstage matching of switch and LNA is designed to achieve low noise figure. To validate the design, the FEM is simulated, fabricated and measured. The experiment results show that, within the range of 7.8-8.1 GHz, the FEM achieves a gain of 22 dB and noise figure of 1.9 dB in receiving mode, with an insertion loss of 0.9 dB and isolation of 40 dB in transmitting mode. In addition, the FEM can handle up to 4 W transmitting power at 8 GHz with good linearity.
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Citation
He Qi, Jun-Ping Geng, Weiren Zhu, Liang Liu, Ziheng Ding, Xianling Liang, Tingting Fan, Xiangzhong Fang, and Rong-Hong Jin, "An 8 GHz Front-End Module with High-Performance T/R Switch and LNA," Progress In Electromagnetics Research C, Vol. 82, 185-197, 2018.
doi:10.2528/PIERC18011007
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