A method of suppressing vibration for high precision broadband laser frequency scanning interferometry

Liu, Guodong; Xu, Xinke; Liu, Bingguo; Chen, Fengdong; Hu, Tao; Lü, Cheng; Guo, Yu

doi:10.7498/aps.65.209501

Acta Phys. Sin.

2016

DOI: 10.7498/aps.65.209501

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A method of suppressing vibration for high precision broadband laser frequency scanning interferometry

Guodong Liu¹,

Xinke Xu²,

Bingguo Liu³

et al.

Abstract: In the paper we study the method of reducing environmental influence in broadband laser frequency scanning interferometer. Target displacement caused by vibration will result in Doppler shift in measurement beat frequency. The extent of frequency shift is usually much larger than the actual target displacement. So the direct calculating of the target distance will cause ranging precision to decrease. In this paper, we establish a model for the influence of environmental vibration on the measurement and analyze… Show more

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Cited by 3 publications

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Vibration Compensation of the Frequency-Scanning-Interferometry-Based Absolute Ranging System

Zhang

Peng

et al. 2019

Applied Sciences

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The frequency-scanning-interferometry-based (FSI-based) absolute ranging technology is a type of ranging technology possessing a high precision and no ranging blind area, so it can be used for non-cooperative targets. However, due to a tiny movement of a target, the Doppler shift and the phase modulation are introduced into the beat signal which results in ranging accuracy decrease. In order to solve this problem, first the model of vibration effect is established, and then the beat signals of two adjacent scanning periods are processed to produce a signal that is immune to vibration. The proposed method is verified by the experiments, and the experimental results show that the effect of vibration compensation is better for the target with a lower vibration velocity and at a lower vibration frequency (lower than 6 Hz). When the target is subjected to a sinusoidal vibration with an amplitude of 10 μm at a frequency of 1 Hz, by using the proposed method the standard deviation is reduced from 775 to 12 μm. Moreover, in the natural environment, by using vibration compensation the standard deviation is reduced from 289 to 11 μm.

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Vibration Compensation of the Frequency-Scanning-Interferometry-Based Absolute Ranging System

Zhang

Peng

et al. 2019

Applied Sciences

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Ultra-low frequency active vibration control for cold atom gravimeter based on sliding-mode robust algorithm

Luo¹,

Cheng²,

Yin³

et al. 2018

Acta Phys. Sin.

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An ultra-low frequency vibrational noise isolation apparatus from external vibration can be a critical factor in many fields such as precision measurement, high-technology manufacturing, scientific instruments, and gravitational wave detection. To increase the accuracies of these experiments, well performed vibration isolation technology is required. Until recently the cold atom gravimeter has played a crucial role in measuring the acceleration due to gravity and earth gravity gradient. The vibration isolation is one of the key techniques in the cold atom gravimeter. To reduce the vibrational noise caused by the reflecting mirror of Raman beams in the cold atom gravimeter, a compact active low-frequency vibration isolation system based on sliding-mode robust control is designed and demonstrated. The sliding-mode robust control active vibration isolation method is used to solve the vibration problem of Raman mirror in the cold atomic gravimeter. The purpose of vibration control is that the controller enables the system to be at zero state as the system states are away from the equilibrium due to vibration disturbance. In this system, the mechanical setup is based on a commercial passive isolation platform which only plays a role at higher frequency. A sliding-mode robust control subsystem is used to process and feed back the vibration measured by a seismometer which can measure the velocity of the ground vibration. A voice coil actuator is used to control and cancel the motion of a passive vibration isolation platform. The simulation and experiment results of vibration isolation platform show, on the one hand, that the vibration noise power spectral density decreases by up to 99.9%, and that the phase noise in cold atom interferometry produced by vibration decreases by up to nearly 85.3% compared with the results of the passive vibration isolation platform. On the other hand, compared with the lead-lag control method, the vibration noise power spectral density decreases by up to 83.3% and the phase noise in cold atom interferometry produced by vibration decreases by nearly 40.2%. Therefore, the sliding-mode robust control has the advantages of less tuning parameters, strong anti-interference ability, and more obvious vibration isolating effect.

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Laser frequency scanning interferometry based on estimating signal parameters via rotational invariance technique

Jing-Xiang¹,

Kong²,

Xu³

2021

Acta Phys. Sin.

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The laser frequency scanning interferometry, as a non-contact method, has non-ranging blind zone and achieves multi-target testing in a single measurement. The beat frequency of target can be extracted by Fourier transform, and then the distance can be solved. However, due to the limitation of laser frequency modulation bandwidth, the resolution of target obtained by Fourier transform is limited to the inherent resolution. In order to solve this problem, in this paper we propose to use the estimating signal parameter via rotational invariance technique (ESPRIT) to perform spectrum analysis on the measured signal. In the experiment, the resampling method is adopted to correct the non-linearity of the measured signal beat frequency, and then the ESPRIT algorithm is used to obtain the target distance. The results show that the Fourier transform algorithm cannot distinguish the target signal from the frequencies of adjacent target, but the ESPRIT algorithm can do. The thickness of the measured target is 2.08 mm. This provides ideas for measuring, such as damage point in the proximity of the fiber, height of thin step, or small hole.

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A method of suppressing vibration for high precision broadband laser frequency scanning interferometry

Cited by 3 publications

References 13 publications

Vibration Compensation of the Frequency-Scanning-Interferometry-Based Absolute Ranging System

Vibration Compensation of the Frequency-Scanning-Interferometry-Based Absolute Ranging System

Ultra-low frequency active vibration control for cold atom gravimeter based on sliding-mode robust algorithm

Laser frequency scanning interferometry based on estimating signal parameters via rotational invariance technique

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