2018
DOI: 10.7498/aps.67.20171884
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Ultra-low frequency active vibration control for cold atom gravimeter based on sliding-mode robust algorithm

Abstract: 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… Show more

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Cited by 6 publications
(3 citation statements)
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“…As mentioned in part III E for increased T , parasitic vibrations limit the sensitivity. Different isolation methods have been used, based on superspring stabilization 70 , or the use of passive isolation platforms 25 , eventually combined with additional active stabilization feedback control [71][72][73][74][75] , or the correlation of the interferometer phase with the remaining vibration noise measured by a classical sensor, either a seismometer 76 , or an accelerometer 77 . The latter method allows for correcting the interferometer phase, either via postcorrection 25 , or feed forward compensation in real time on the Raman lasers phase difference 77 .…”
Section: Sensitivity Limitsmentioning
confidence: 99%
“…As mentioned in part III E for increased T , parasitic vibrations limit the sensitivity. Different isolation methods have been used, based on superspring stabilization 70 , or the use of passive isolation platforms 25 , eventually combined with additional active stabilization feedback control [71][72][73][74][75] , or the correlation of the interferometer phase with the remaining vibration noise measured by a classical sensor, either a seismometer 76 , or an accelerometer 77 . The latter method allows for correcting the interferometer phase, either via postcorrection 25 , or feed forward compensation in real time on the Raman lasers phase difference 77 .…”
Section: Sensitivity Limitsmentioning
confidence: 99%
“…As mentioned in part III E for increased T , parasitic vibrations limit the sensitivity. Different isolation methods have been used, based on superspring stabilization 65 , or the use of passive isolation platforms 25 , eventually combined with additional active stabilization feedback control [66][67][68][69] , or the correlation of the interferometer phase with the remaining vibration noise measured by a classical sensor, either a seismometer 70 , or an accelerometer 71 . The latter method allows for correcting the interferometer phase, either via postcorrection 25 , or feed forward compensation in real time on the Raman lasers phase difference 71 .…”
Section: Sensitivity Limitsmentioning
confidence: 99%
“…Whether it is the compensation of vibration noise or the rough estimate of gravity value, the accelerometer is required to have high precision, so the error of the accelerometer itself cannot be ignored. However, due to the influence of environmental factors such There are mainly three methods for suppressing vibration noise: passive vibration isolation based on super springs [51], active vibration isolation with feedback control [52][53][54], and using a motion sensor such as a seismometer or accelerometer to measure vibration noise and compensate [46,48]. In practical application, in the case of obvious external vibration and large interference, the vibration compensation method has a better effect than the active and passive vibration isolation methods.…”
Section: Error From Accelerometermentioning
confidence: 99%