Your search keyword '"gravimeter comparison"' showing total 5 results

1. Traceability of the Hannover FG5X-220 to the SI Units

Author

Schilling, Manuel, Timmen, Ludger, Rizos, Chris, Series Editor, Freymueller, Jeffrey T., editor, and Sánchez, Laura, editor

Published

2018

2. RFCAG2013: Russian-Finnish comparison of absolute gravimeters in 2013

Author

Mäkinen J., Sermyagin R.A., Oshchepkov I.A., Basmanov A.V., Pozdnyakov A.V., Yushkin V.D., Stus Yu.F., and Nosov D.A.

Subjects

absolute gravimeter, field absolute gravimeter, gravimeter comparison, key comparison, Geodesy, QB275-343

Abstract

In June–July 2013,we performed a comparison of five absolute gravimeters of different types. The gravimeters were the FG5X-221 of the FGI, the FG5-110 and GBL-M 002 of the TsNIIGaiK, the GABL-PM of the IAE SB RAS, and the GABL-M of the NIIMorGeofizika (Murmansk, Russia). The three last-mentioned are field-type portable gravimeters made by the Institute of Automation and Electrometry in Novosibirsk, and this is the first international comparison for them. This Russian-Finnish Comparison of Absolute Gravimeters RFCAG2013 was conducted at four sites with different characteristics: at the field sites Pulkovo and Svetloe near St. Petersburg, and at the laboratory sites TsNIIGaIK in Moscow and Zvenigorod near Moscow. At the TsNIIGAiK site and at Zvenigorod two piers were used, such that altogether six stations were occupied. The FG5X- 221 provides the link to the CCM.G-K2 Key Comparison in Luxembourg in November 2013. Recently, the Consultative Committee for Mass and Related Quantities and the International Association of Geodesy drafted a strategy on how to best transmit the results of Key Comparisons of absolute gravimeters to benefit the geodetic and geophysical gravimetric community. Our treatment of the RFCAG2013 presents one of the first practical applications of the ideas of the strategy document, andwe discuss the resulting uncertainty structure. Regarding the comparison results, we find the gravimeters show consistent offsets at the quite different sites. All except one gravimeter are in equivalence.

Published

2016

3. Traceability of the Hannover FG5X-220 to the SI units

Author

Ludger Timmen and Manuel Schilling

Subjects

Dewey Decimal Classification::500 | Naturwissenschaften::550 | Geowissenschaften, Physics::Optics, Absolute value, Frequency standard, law.invention, Length measurement, Optics, law, gravimeter comparison, Unit of length, ddc:550, Physics::Atomic Physics, Konferenzschrift, Physics, Metrologie, Frequenzstandard, Gravimetervergleich, business.industry, Gravimeter, Astrophysics::Instrumentation and Methods for Astrophysics, Laser, Metrology, Interferometry, metrology, frequency standard, SI units, absolute gravimetry, Absolut Gravimetrie, SI Einheiten, Absolutgravimetrie, business

Abstract

The absolute measurement of g is currently realized through the laser interferometric measurement of a free falling retro-reflector. The Micro-g LaCoste FG5X is a free-fall gravimeter with a laser interferometer in Mach-Zehnder configuration which uses simultaneous time and distance measurements to calculate the absolute value of g. Because the instrument itself contains the necessary working standards for precise time and length measurements, it is considered independent of external references. The timing is kept with a 10 MHz rubidium oscillator with a stability of 5×10e−10 . The length unit is realized by the laser interferometer. The frequency calibrated and iodine stabilized helium-neon laser has a wavelength of 633 nm and an accuracy of 2.5×10e−11. In 2012 the FG5-220 of the Institut für Erdmessung (IfE) was upgraded to the FG5X-220. The upgrade included a new dropping chamber with a longer free fall and new electronics including a new rubidium oscillator. The metrological traceability to measurement units of the Système International d’unités (SI unit) is ensured by two complementary and successive approaches: the comparison of frequencies with standards of higher order and the comparison of the measured g to a reference measured by absolute gravimeters defined as primary standards within the SI. A number of experiments to test the rubidium oscillator were performed. The oscillator showed a linear drift of 0.2×10e−3 Hz per month (=0.3 nm/s² per month) in the first 18 months of use. A jump in the frequency of 0.01 Hz (=20 nm/s² ) was revealed recently and the drift rate changed to −0.5×10e−3 Hz /month.

Published

2016

4. Traceability of the Hannover FG5X-220 to the SI units

Author

Schilling, Manuel, Timmen, Ludger, Schilling, Manuel, and Timmen, Ludger

Abstract

The absolute measurement of g is currently realized through the laser interferometric measurement of a free falling retro-reflector. The Micro-g LaCoste FG5X is a free-fall gravimeter with a laser interferometer in Mach-Zehnder configuration which uses simultaneous time and distance measurements to calculate the absolute value of g. Because the instrument itself contains the necessary working standards for precise time and length measurements, it is considered independent of external references. The timing is kept with a 10MHz rubidium oscillator with a stability of 5x10e-10. The length unit is realized by the laser interferometer. The frequency calibrated and iodine stabilized helium-neon laser has a wavelength of 633 nm and an accuracy of 2.5x10e-11. In 2012 the FG5-220 of the Institut für Erdmessung (IfE) was upgraded to the FG5X-220. The upgrade included a new dropping chamber with a longer free fall and new electronics including a new rubidium oscillator. The metrological traceability to measurement units of the Système International d’unités (SI unit) is ensured by two complementary and successive approaches: the comparison of frequencies with standards of higher order and the comparison of the measured g to a reference measured by absolute gravimeters defined as primary standards within the SI. A number of experiments to test the rubidium oscillator were performed. The oscillator showed a linear drift of 0.2x10e-3 Hz per month (= 0.3 nm/s² per month) in the first 18 months of use. A jump in the frequency of 0.01 Hz (=20 nm/s²) was revealed recently and the drift rate changed to 0.4x10e-3 Hz/month.

Published

2016

5. Traceability of the Hannover FG5X-220 to the SI units

Author

Schilling, Manuel, Timmen, Ludger, Schilling, Manuel, and Timmen, Ludger

Abstract

The absolute measurement of g is currently realized through the laser interferometric measurement of a free falling retro-reflector. The Micro-g LaCoste FG5X is a free-fall gravimeter with a laser interferometer in Mach-Zehnder configuration which uses simultaneous time and distance measurements to calculate the absolute value of g. Because the instrument itself contains the necessary working standards for precise time and length measurements, it is considered independent of external references. The timing is kept with a 10 MHz rubidium oscillator with a stability of 5×10e−10 . The length unit is realized by the laser interferometer. The frequency calibrated and iodine stabilized helium-neon laser has a wavelength of 633 nm and an accuracy of 2.5×10e−11. In 2012 the FG5-220 of the Institut für Erdmessung (IfE) was upgraded to the FG5X-220. The upgrade included a new dropping chamber with a longer free fall and new electronics including a new rubidium oscillator. The metrological traceability to measurement units of the Système International d’unités (SI unit) is ensured by two complementary and successive approaches: the comparison of frequencies with standards of higher order and the comparison of the measured g to a reference measured by absolute gravimeters defined as primary standards within the SI. A number of experiments to test the rubidium oscillator were performed. The oscillator showed a linear drift of 0.2×10e−3 Hz per month (=0.3 nm/s² per month) in the first 18 months of use. A jump in the frequency of 0.01 Hz (=20 nm/s² ) was revealed recently and the drift rate changed to −0.5×10e−3 Hz /month.

Published

2015