Z. Liu scite author profile

Proton precession magnetometer is a high-precision device for weak magnetostatic field measurement. The measurement accuracy depends on the frequency measurement of free induction decay (FID) signal, while the signal to noise ratio (SNR) is an important factor affecting the results. Many signal processing methods have been proposed to improve the SNR of FID signal. However, the theoretical analysis of different types of noises for FID signal has not be conducted yet. In addition, the relationship between the frequency measurement accuracy and SNR has not been explicitly established and quantified. This paper first proposes a background noise model based on the extracted features from the FID signal. With this model, background noises, such as white noise, narrow-band noise, and phase noise etc., can be calculated and estimated. Secondly, the relationship between the frequency measurement accuracy and SNR is identified. We also built a prototype proton magnetometer for field tests and validation purpose. Experiments were conducted to investigate this relation through simulation. Different values for frequency accuracy were obtained with different SNRs from the acquired FID signals from field tests. The consistence between the measurement and computational results is observed. When SNR is larger than 30 dB, the absolute frequency accuracy becomes constant which is about 0.04 Hz. With the stability taken into account, the accuracy can be better even when the SNR is higher than 30 dB. This study provides a reference to optimize the design of proton precession magnetometer and the frequency calculation for FID signal. K: Models and simulations; Instrumental noise; Data analysis; Detector control systems (detector and experiment monitoring and slow-control systems, architecture, hardware, algorithms, databases)1Corresponding author.

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Construction of an Overhauser magnetic gradiometer and the applications in geomagnetic observation and ferromagnetic target localization

Liu

et al. 2017

J. Inst.

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The proton precession magnetometer with single sensor is commonly used in geomagnetic observation and magnetic anomaly detection. Due to technological limitations, the measurement accuracy is restricted by several factors such as the sensor performance, frequency measurement precision, instability of polarization module, etc. Aimed to improve the anti-interference ability, an Overhauser magnetic gradiometer with dual sensor structure was designed. An alternative design of a geomagnetic sensor with differential dual-coil structure was presented. A multi-channel frequency measurement algorithm was proposed to increase the measurement accuracy. A silicon oscillator was adopted to resolve the instability of polarization system. This paper briefly discusses the design and development of the gradiometer and compares the data recorded by this instrument with a commonly used commercially Overhauser magnetometer in the world market. The proposed gradiometer records the earth magnetic field in 24 hours with measurement accuracy of ± 0.3 nT and a sampling rate of 3 seconds per sample. The quality of data recorded is excellent and consistent with the commercial instrument. In addition, experiments of ferromagnetic target localization were conducted. This gradiometer shows a strong ability in magnetic anomaly detection and localization.To sum up, it has the advantages of convenient operation, high precision, strong anti-interference, etc., which proves the effectiveness of the dual sensor structure Overhauser magnetic gradiometer. K: Manufacturing; Detector design and construction technologies and materials; Instrument optimisation; Space instrumentation 1Corresponding author.

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Z. Liu

A new¹⁸F-heteroaryltrifluoroborate radio-prosthetic with greatly enhanced stability that is labelled by¹⁸F–¹⁹F-isotope exchange in good yield at high specific activity

Noise characterization for the FID signal from proton precession magnetometer

Construction of an Overhauser magnetic gradiometer and the applications in geomagnetic observation and ferromagnetic target localization

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Z. Liu

A new18F-heteroaryltrifluoroborate radio-prosthetic with greatly enhanced stability that is labelled by18F–19F-isotope exchange in good yield at high specific activity

Noise characterization for the FID signal from proton precession magnetometer

Construction of an Overhauser magnetic gradiometer and the applications in geomagnetic observation and ferromagnetic target localization

Contact Info

Product

Resources

About

A new¹⁸F-heteroaryltrifluoroborate radio-prosthetic with greatly enhanced stability that is labelled by¹⁸F–¹⁹F-isotope exchange in good yield at high specific activity