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PIER PIER B PIER C PIER M PIER Letters
2020-10-14
Application of Digital Lock-in Amplifier in Complex Electromagnetic Interference of Substation
By
Jiabing Song,

    Dr. Jiabing Song

    China University of Geosciences

    China

    Homepage

Hengli Song,

    Dr. Hengli Song

    School of Automation

    China University of Geosciences

    China

    Homepage

Xuan Yang,

    Dr. Xuan Yang

    School of Automation

    China University of Geosciences

    China

    Homepage

Haobin Dong

    Dr. Haobin Dong

    School of Automation

    China University of Geosciences

    China

    Homepage

Progress In Electromagnetics Research C, Vol. 106, 105-120, 2020
doi:10.2528/PIERC20071001
Abstract
There is complex electromagnetic interference in the substation. In order to improve detection accuracy, a digital lock-in amplifier is used in the detection of the grounding grid. This paper introduces the principle of non-destructive testing of grounding grid based on electromagnetic method. Firstly, the distribution characteristics of surface magnetic induction intensity at different frequencies are obtained by CDEGS simulation. At the same time, it describes the principle and structure of an orthogonal vector type digital lock-in amplifier in detail. In order to realize the high-precision grounding grid detection system, the hardware circuit of the digital lock-in amplifier is designed by FPGA and analog-to-digital converter. The digital lock-in amplifier algorithm is implemented in the FPGA. Finally, the digital lock-in amplifier is tested. The test results show that when the signal-to-noise ratio of the signal to be tested is -20 db, the signal amplitude measurement error is less than 3%. The designed digital lock-in amplifier is applied to the actual grounding grid detection, and the topology and corrosion of the grounding network can be detected. Therefore, the digital lock-in amplifier can be effectively applied to non-destructive testing of grounding grid.
Citation
Jiabing Song, Hengli Song, Xuan Yang, and Haobin Dong, "Application of Digital Lock-in Amplifier in Complex Electromagnetic Interference of Substation," Progress In Electromagnetics Research C, Vol. 106, 105-120, 2020.
doi:10.2528/PIERC20071001
References

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8. Fu, Z., X. Wang, Q. Wang, et al. "Advances and challenges of corrosion and topology detection of grounding grid," Applied Sciences, Vol. 9, No. 11, 2290, 2019.
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9. Song, H., H. Dong, and P. Zhang, "A virtual instrument for diagnosis to substation grounding grids in harsh electromagnetic environment," IEEE International Instrumentation and Measurement Technology Conference (I2MTC), 1-6, 2017.

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