Distortion-free frequency response measurements

Xiao Zhang; He Yin; Rui Li; Jiaying Hong; Chengming Wang; Shengnan Ai; Juicheng Hsieh; Bin He; Zhengyu Chen; Qin Li; Ping Xue

doi:10.1088/1361-6463/ab9784

Distortion-free frequency response measurements

Xiao Zhang^*, He Yin, Rui Li, Jiaying Hong, Chengming Wang, Shengnan Ai, Juicheng Hsieh, Bin He, Zhengyu Chen, Qin Li, Ping Xue

^*Corresponding author for this work

School of Medical and Technology

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

7 Citations (Scopus)

Abstract

We propose and experimentally demonstrate a distortion-free network analyzer (DFNA) using a noise source and an average power sensor for measuring the frequency property of an electronic device. DFNA makes use of the global algorithm and therefore typically save 60% measurements than conventional network analyzer which measures frequency response locally, under the same conditions. Furthermore, conventional network analyzer could be significantly affected by distortion due to its direct point-by-point scanning manner in frequency domain. In contrast, by utilizing the coincidence measurement principle, DFNA shows strong robustness against distortion. The results demonstrate that the proposed technique provides an efficient and robust way for anti-distortion frequency response analysis and has potential applications in communications, radio frequency circuits, radar and even electronic warfare.

Original language	English
Article number	39LT02
Journal	Journal Physics D: Applied Physics
Volume	53
Issue number	39
DOIs	https://doi.org/10.1088/1361-6463/ab9784
Publication status	Published - 23 Sept 2020

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title = "Distortion-free frequency response measurements",

abstract = "We propose and experimentally demonstrate a distortion-free network analyzer (DFNA) using a noise source and an average power sensor for measuring the frequency property of an electronic device. DFNA makes use of the global algorithm and therefore typically save 60% measurements than conventional network analyzer which measures frequency response locally, under the same conditions. Furthermore, conventional network analyzer could be significantly affected by distortion due to its direct point-by-point scanning manner in frequency domain. In contrast, by utilizing the coincidence measurement principle, DFNA shows strong robustness against distortion. The results demonstrate that the proposed technique provides an efficient and robust way for anti-distortion frequency response analysis and has potential applications in communications, radio frequency circuits, radar and even electronic warfare.",

author = "Xiao Zhang and He Yin and Rui Li and Jiaying Hong and Chengming Wang and Shengnan Ai and Juicheng Hsieh and Bin He and Zhengyu Chen and Qin Li and Ping Xue",

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T1 - Distortion-free frequency response measurements

AU - Zhang, Xiao

AU - Yin, He

AU - Li, Rui

AU - Hong, Jiaying

AU - Wang, Chengming

AU - Ai, Shengnan

AU - Hsieh, Juicheng

AU - He, Bin

AU - Chen, Zhengyu

AU - Li, Qin

AU - Xue, Ping

PY - 2020/9/23

Y1 - 2020/9/23

N2 - We propose and experimentally demonstrate a distortion-free network analyzer (DFNA) using a noise source and an average power sensor for measuring the frequency property of an electronic device. DFNA makes use of the global algorithm and therefore typically save 60% measurements than conventional network analyzer which measures frequency response locally, under the same conditions. Furthermore, conventional network analyzer could be significantly affected by distortion due to its direct point-by-point scanning manner in frequency domain. In contrast, by utilizing the coincidence measurement principle, DFNA shows strong robustness against distortion. The results demonstrate that the proposed technique provides an efficient and robust way for anti-distortion frequency response analysis and has potential applications in communications, radio frequency circuits, radar and even electronic warfare.

AB - We propose and experimentally demonstrate a distortion-free network analyzer (DFNA) using a noise source and an average power sensor for measuring the frequency property of an electronic device. DFNA makes use of the global algorithm and therefore typically save 60% measurements than conventional network analyzer which measures frequency response locally, under the same conditions. Furthermore, conventional network analyzer could be significantly affected by distortion due to its direct point-by-point scanning manner in frequency domain. In contrast, by utilizing the coincidence measurement principle, DFNA shows strong robustness against distortion. The results demonstrate that the proposed technique provides an efficient and robust way for anti-distortion frequency response analysis and has potential applications in communications, radio frequency circuits, radar and even electronic warfare.

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JO - Journal Physics D: Applied Physics

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Distortion-free frequency response measurements

Abstract

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