A 13–33 GHz Wideband Low-Noise Amplifier in 150-nm GaAs Based on Simultaneous Noise- and Input-Matched Gain-Core with R-L-C Shunt Feedback Network

Seonyeong Hwang; Dongwan Kang; Yeonggeon Lee; Dae Woong Park

doi:10.3390/electronics14030450

A 13–33 GHz Wideband Low-Noise Amplifier in 150-nm GaAs Based on Simultaneous Noise- and Input-Matched Gain-Core with R-L-C Shunt Feedback Network

Seonyeong Hwang, Dongwan Kang, Yeonggeon Lee, Dae Woong Park

Dept. of Semiconductor Engineering

Seoul National University of Science and Technology (SNUST)

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

This work reports the concept of a shunt negative feedback technique for implementing a millimeter-wave wideband low-noise amplifier. The proposed shunt negative feedback network consists of a resistor–capacitor–inductor configuration. The proposed feedback network can achieve simultaneous noise and input matching (SNIM) over a wide frequency range by adjusting the values of the resistor–capacitor–inductor configuration based on numerical analysis. By adopting the SNIM-based gain core as the first stage of the amplifier, the simulation results of the three-stage low-noise amplifier in a 150-nm GaAs pHEMT process achieve a gain of 15.6–18.6 dB and a noise figure of 1.05–2.8 dB in the frequency range of 13–33 GHz, respectively, while dissipating 99 mW.

Original language	English
Article number	450
Journal	Electronics (Switzerland)
Volume	14
Issue number	3
DOIs	https://doi.org/10.3390/electronics14030450
State	Published - Feb 2025

Keywords

amplifier
gallium arsenide
integrated circuits
low-noise amplifier
millimeter wave
simultaneous input and noise matching
wideband

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10.3390/electronics14030450

Cite this

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title = "A 13–33 GHz Wideband Low-Noise Amplifier in 150-nm GaAs Based on Simultaneous Noise- and Input-Matched Gain-Core with R-L-C Shunt Feedback Network",

abstract = "This work reports the concept of a shunt negative feedback technique for implementing a millimeter-wave wideband low-noise amplifier. The proposed shunt negative feedback network consists of a resistor–capacitor–inductor configuration. The proposed feedback network can achieve simultaneous noise and input matching (SNIM) over a wide frequency range by adjusting the values of the resistor–capacitor–inductor configuration based on numerical analysis. By adopting the SNIM-based gain core as the first stage of the amplifier, the simulation results of the three-stage low-noise amplifier in a 150-nm GaAs pHEMT process achieve a gain of 15.6–18.6 dB and a noise figure of 1.05–2.8 dB in the frequency range of 13–33 GHz, respectively, while dissipating 99 mW.",

keywords = "amplifier, gallium arsenide, integrated circuits, low-noise amplifier, millimeter wave, simultaneous input and noise matching, wideband",

author = "Seonyeong Hwang and Dongwan Kang and Yeonggeon Lee and Park, \{Dae Woong\}",

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year = "2025",

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doi = "10.3390/electronics14030450",

language = "English",

volume = "14",

journal = "Electronics (Switzerland)",

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T1 - A 13–33 GHz Wideband Low-Noise Amplifier in 150-nm GaAs Based on Simultaneous Noise- and Input-Matched Gain-Core with R-L-C Shunt Feedback Network

AU - Hwang, Seonyeong

AU - Kang, Dongwan

AU - Lee, Yeonggeon

AU - Park, Dae Woong

PY - 2025/2

Y1 - 2025/2

N2 - This work reports the concept of a shunt negative feedback technique for implementing a millimeter-wave wideband low-noise amplifier. The proposed shunt negative feedback network consists of a resistor–capacitor–inductor configuration. The proposed feedback network can achieve simultaneous noise and input matching (SNIM) over a wide frequency range by adjusting the values of the resistor–capacitor–inductor configuration based on numerical analysis. By adopting the SNIM-based gain core as the first stage of the amplifier, the simulation results of the three-stage low-noise amplifier in a 150-nm GaAs pHEMT process achieve a gain of 15.6–18.6 dB and a noise figure of 1.05–2.8 dB in the frequency range of 13–33 GHz, respectively, while dissipating 99 mW.

AB - This work reports the concept of a shunt negative feedback technique for implementing a millimeter-wave wideband low-noise amplifier. The proposed shunt negative feedback network consists of a resistor–capacitor–inductor configuration. The proposed feedback network can achieve simultaneous noise and input matching (SNIM) over a wide frequency range by adjusting the values of the resistor–capacitor–inductor configuration based on numerical analysis. By adopting the SNIM-based gain core as the first stage of the amplifier, the simulation results of the three-stage low-noise amplifier in a 150-nm GaAs pHEMT process achieve a gain of 15.6–18.6 dB and a noise figure of 1.05–2.8 dB in the frequency range of 13–33 GHz, respectively, while dissipating 99 mW.

KW - amplifier

KW - gallium arsenide

KW - integrated circuits

KW - low-noise amplifier

KW - millimeter wave

KW - simultaneous input and noise matching

KW - wideband

UR - https://www.scopus.com/pages/publications/85217784105

U2 - 10.3390/electronics14030450

DO - 10.3390/electronics14030450

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JO - Electronics (Switzerland)

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ER -

A 13–33 GHz Wideband Low-Noise Amplifier in 150-nm GaAs Based on Simultaneous Noise- and Input-Matched Gain-Core with R-L-C Shunt Feedback Network

Abstract

Keywords

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