A new ellipse fitting method of the minimum differential-mode noise in the atom interference gravimeter

Xu, Aopeng; Wang, Zhaoying; Kong, Delong; Fu, Zhijie; Lin, Qiang

doi:10.1088/1674-1056/27/7/070203

Cited by 6 publications

(6 citation statements)

References 22 publications

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“…The standard ellipse fitting approach described in reference 45 has been extended and enhanced 46,47 . However, again for simplicity, we use the standard method where the phase difference is found from fitting an ellipse of the form 45 ,…”

Section: Cold Atom Gravity Gradiometersmentioning

confidence: 99%

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Position fixing with cold atom gravity gradiometers

Phillips,

Wright,

Riou

et al. 2022

Preprint

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This paper proposes a position fixing method for autonomous navigation using partial gravity gradient solutions from cold atom interferometers. Cold atom quantum sensors can provide ultra-precise measurements of inertial quantities, such as acceleration and rotation rates. However, we investigate the use of pairs of cold atom interferometers to measure the local gravity gradient and to provide position information by referencing these measurements against a suitable database. Simulating the motion of a vehicle, we use partial gravity gradient measurements to reduce the positional drift associated with inertial navigation systems. Using standard open source global gravity databases, we show stable navigation solutions for trajectories of over 1000km.

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Section: Cold Atom Gravity Gradiometersmentioning

confidence: 99%

“…The pairs of measurements lie on an ellipsebecause the phase of the reference laser is unknown and varies over time. The gradient is found by fitting an ellipse to a set of measurements [45][46][47] . This presents a potential problem for the use of this method when the gradiometer is moving relative to the reference field.…”

Section: Introductionmentioning

confidence: 99%

Position fixing with cold atom gravity gradiometers

Phillips,

Wright,

Riou

et al. 2022

Preprint

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“…A commercial software is used to correct the measured transfer function of the seismometer, obtaining the actual motion of the mirror. Experimental results have demonstrated that it improved the measurement sensitivity of absolute gravimeters by 3-4 times [20,21]. The National University of Defense Technology in China conducts a detailed analysis of the measurement noise introduced by vertical and horizontal coupling-induced vibration.…”

Section: Introductionmentioning

confidence: 99%

A vibration correction system for cold atom gravimeter

Guo,

Bai,

et al. 2023

Meas. Sci. Technol.

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Cold atom gravimeters are used to measure the absolute value of the gravitational acceleration. To mitigate the influence of seismic noise on the mirror, a vibration correction system is used. A commercial seismometer CMG-3ESPC is employed to measure the mirror vibration. The transfer function between the mirror vibration and the output of the seismometer is regarded as a proportional element with a time delay. The best proportional element and the best time delay are obtained by minimizing the standard deviation of the fitting residuals of the interference fringe α − P with vibration correction. This system not only exhibits excellent environmental adaptability but also eliminates the need for rough estimation of local gravitational acceleration during the vibration correction process. The system was built on the homemade cold atom gravimeter to carry out experiments in the laboratory. Compared with the measurement results without vibration correction, the standard deviation of the gravity measurement results was reduced from 120.5 μ Gal to 4.2 μ Gal, resulting in a significant reduction by a factor of 28.7. Meanwhile, its sensitivity was significantly improved from 330.8 μ Gal Hz − 1 to 18.0 μ Gal Hz − 1 by performing vibration correction. In the future, this system is expected to carry out comprehensive verification experiments in more complex noisy environments.

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“…Various methods for fitting ellipses can be found in the literature [15][16][17][18][19]. One can distinguish between geometric fitting methods, which minimise the distance between the data points and the fitted ellipse (in the x-y plane), and algebraic methods, which minimise a certain function of x and y.…”

mentioning

confidence: 99%

“…However, geometric methods have the advantage of minimising the error between the fit and the data in a more satisfactory manner; for detailed discussions of the issues involved the reader is referred to references [1,[16][17][18].…”

mentioning

confidence: 99%

An investigation of errors in ellipse-fitting for cold-atom interferometers

Ridley,

Rodgers

2023

Preprint

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Ellipse fitting is a technique which is used to extract differential phase in cold-atom interferometers, particularly in situations where common-mode noise needs to be suppressed. We use numerical simulation to investigate errors in the ellipse fitting process; specifically, errors due to the presence of additive noise, linear drift in ellipse offset and amplitude, as well as an error that can arise from fringe normalisation. Errors are found to manifest in two ways: bias in the ellipse phase measurement and incomplete suppression of common mode phase noise. We quantify these errors for three different ellipse fitting algorithms and discuss the applicability of these results to future cold atom sensors.

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A new ellipse fitting method of the minimum differential-mode noise in the atom interference gravimeter

Cited by 6 publications

References 22 publications

Position fixing with cold atom gravity gradiometers

Position fixing with cold atom gravity gradiometers

A vibration correction system for cold atom gravimeter

An investigation of errors in ellipse-fitting for cold-atom interferometers

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