Experimental Validation for Moving Particle Detection Using Acoustic Emission Method

Gas-insulated switchgears (GISs) are important pieces of power equipment used to improve the reliability of power facilities. As the number of GISs increases, more insulation failures occur every year. The most common cause of insulation failure is particles and foreign bodies producing a partial discharge (PD), which causes deterioration of the insulation materials and results in insulation breakdown. However, it is not easy to detect them by conventional PD and ultra-high frequency (UHF) PD measurements because it is difficult to apply the conventional method to the GISs in service, and the UHF method is not always applicable to GISs. Therefore, an appropriate method to detect particles and foreign bodies in GISs is needed. In this study, experimental validation was performed to detect particles moving in GISs using the acoustic emission (AE) method. Acoustic wave signals were produced by the particles moving on the surface of a flat plate when applying voltage. An AE sensor with a frequency range of 50 to 400 kHz was used, and a decoupler and low-noise amplifier were designed to detect the acoustic wave signals with high sensitivity. Twelve types of particles were used, and one was selected to confirm the detectable minimum output voltage. In an actual factory test, the output voltage of the acoustic wave signals was analyzed while considering the applied voltage and signal attenuation. Consequently, it was confirmed that the AE measuring system proposed in this paper could detect particles moving inside GISs.

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CMOS Front-End of LNA for GPS and GSM wireless applications

International Journal of Engineering & Technology ◽

10.14419/ijet.v7i1.5.9069 ◽

2017 ◽

Vol 7 (1.5) ◽

pp. 1

Author(s):

Mahesh Mudavath ◽

K. Hari Kishore

Keyword(s):

Power Dissipation ◽

Simulation Analysis ◽

Noise Figure ◽

Low Cost ◽

High Sensitivity ◽

Low Noise ◽

Frequency Range ◽

Wireless Applications ◽

Noise Amplifier ◽

Intercept Point

This paper describes a layout of a CMOS Low Noise Amplifier for reconfigurable packages which include GPS, GSM Wi-Fi applications. The improvement of a notably linear Radio front-stop, able to function with Galileo and GPS satellite signals suitable for coexisting in a mobile opposed environment for area based offerings, pleasing the fundamental necessities for a mass market product which includes low cost, low footprint, good accuracy, low strength intake and high sensitivity. primarily based on a wideband enter matching, the LNA stages cowl all band of hobby even as reaching a great change-off between excessive gain, low noise parent and coffee electricity intake. The complete simulation analysis of the circuit results in the frequency range of 1.4 GHz to 2 GHz. The noise figure is 1.8 dB at 1.4GHz and rises to 3.4 dB at 2 GHz. The input return and output return losses (S11, S22) of the LNA at a frequency range between 1.4 GHz and 2 GHz are S11= -12 dB, S22 =-44.73 dB at 1.77 GHz and S22 =-26.47 dB at 2 GHz. The overall gain of the LNA (S21) is 13 dB at 1.4025 GHz, 3rd order input intercept point (IIP3) = -3.16 dBm and -1dB compression point is -12.56 dBm. Input Impedance of 50Ω, 3dB Power Bandwidth of 450MHz, and Power Dissipation of 2.7mW at 1.2V power supply.

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A low noise amplifier with on-chip matching network and integrated bulk Acoustic Wave resonators for high image rejection

2009 Ph.D. Research in Microelectronics and Electronics ◽

10.1109/rme.2009.5201313 ◽

2009 ◽

Cited By ~ 3

Author(s):

Markus Dielacher ◽

Martin Flatscher ◽

Wolfgang Pribyl

Keyword(s):

Acoustic Wave ◽

Low Noise ◽

Low Noise Amplifier ◽

Bulk Acoustic Wave ◽

Image Rejection ◽

Matching Network ◽

Noise Amplifier ◽

On Chip ◽

Acoustic Wave Resonators ◽

Bulk Acoustic Wave Resonators

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Design and Simulation of S-Band Low Noise Amplifier Based on ATF-54143

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.577.615 ◽

2014 ◽

Vol 577 ◽

pp. 615-619

Author(s):

Hai Peng Wang ◽

Shu Hui Yang ◽

Meng Lu Feng ◽

Yin Chao Chen

Keyword(s):

Standing Wave ◽

Output Voltage ◽

Noise Figure ◽

High Electron Mobility Transistor ◽

Input Voltage ◽

Low Noise ◽

Simulation Software ◽

Voltage Standing Wave Ratio ◽

High Electron ◽

Noise Amplifier

This design used a low noise enhanced high electron mobility transistor ATF54143 and Agilent's ADS simulation software to achieve the good performance of operating frequency at 2.45GHz, noise figure (NF) is less than 0.8dB, band gain (S21) is greater than 15dB, input voltage standing-wave ratio (VSWR1) is less than 1.4dB, output voltage standing-wave ratio (VSWR2) is less than 1.6dB.

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A new method of fluxgate signal extraction

Information extraction and processing ◽

10.15407/vidbir2017.45.083 ◽

2017 ◽

Vol 2017 (45) ◽

pp. 83-89

Author(s):

A.A. Marusenkov ◽

Keyword(s):

High Frequency ◽

Second Harmonic ◽

Excitation Frequency ◽

Low Noise ◽

Measuring System ◽

Signal Extraction ◽

Fluxgate Magnetometer ◽

New Approach ◽

Average Value ◽

The Time Domain

Using dedicated high-frequency measuring system the distribution of the Barkhausen jumps intensity along a reversal magnetization cycle was investigated for low noise fluxgate sensors of various core shapes. It is shown that Barkhausen (reversal magnetization) noise intensity is strongly inhomogeneous during an excitation cycle. In the traditional second harmonic fluxgate magnetometers the signals are extracted in the frequency domain, as a result, some average value of reversal magnetization noises is contributed to the output signals. In order to fit better the noise shape and minimize its transfer to the magnetometer output the new approach for demodulating signals of these sensors is proposed. The new demodulating method is based on information extraction in the time domain taking into account the statistical properties of cyclic reversal magnetization noises. This approach yields considerable reduction of the fluxgate magnetometer noise in comparison with demodulation of the signal filtered at the second harmonic of the excitation frequency.

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