Abstract
The article represents the results of a comparative analysis of existing gravimeters of aviation gravimetric system and identifies their strengths and weaknesses. It also represents and considers structures of the existing types of gravimeters that are used as elements of aviation gravimetric systems, and analyzes metrological characteristics of such sensitive elements. The paper describes modern advanced developments in the field of construction of innovative aviation gravimeters.
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References
Williams, S., MacQueen, J.D.: Development of a versatile, commercially proven, and cost-effective airborne gravity system. Lead. Edge 20(6), 651–654 (2001)
Korobiichuk, I., Nowicki, M., Szewczyk, R.: Design of the novel double-ring dynamical gravimeter. J. Autom. Mob. Robot. Intell. Syst. 9(3), 47–51 (2015)
Bezvesilna O.M.: Aviation gravimetric systems and gravimeters. Monograph, vol. 604. ZSTU, Zhytomyr (2007)
Korobiichuk, I., Bezvesilna, O., Kachniarz, M., Tkachuk, A., Chilchenko, T.: Two-channel MEMS gravimeter of the automated aircraft gravimetric system. In: Szewczyk, R., Kaliczyńskam, M. (eds.) Recent Advances in Systems, Control and Information Technology, vol. 543, pp. 481–487. Springer, Heidelberg (2017)
Popov E.I.: Motion-base gravity determination, vol. 218. Nauka, Moscow (1987)
Krasnov, A.A., Nesenyuk, L.P., Peshekhonov, V.G., Sokolov, A.V., Elinson, L.S.: Integrated marine gravimetric system. Development and operation results. Gyroscopy Navig. 2(2), 75–81 (2011)
Veselov K.E.: Gravimetric survey. M. Nedra, 512 p. (1968)
Forsberg, R., Olesen, A.V., Einarsson, I.: Airborne gravimetry for geoid determination with Lacoste Romberg and Chekan gravimeters. Gyroscopy Navig. 6(4), 265–270 (2015)
Cai, S., Zhang, K., Wu, M., Huang, Y.: Long-term stability of the SGA-WZ strapdown airborne gravimeter. Sensors (Switzerland) 12(8), 11091–11099 (2012)
Graf, A.: Gravimetry. Principles of Measurement, vol. 112. Nauka, Moscow (1961)
Gravimeter GI1/1/ Ramensky Instrument Engineering Plant. http://www.rpz.ru/products/other_system/gravimetr_gi_11/
Mobile gravimeters “Chekan-AM” OJSC Concern “CSRI “Elektropribor”. http://www.elektropribor.spb.ru/ru/rprod6-1.html
Gravimeter “Grin-2000”, SSC “Yuzhmorgeologia”. http://www.ymg.ru/ru/content/gravimetr
Air gravimeter MAG-1 M, CJSC Gravimetric technologies. http://aerogeo.ru/index.php?option=com_content&view=article&id=76%3A2009-10-15-13-37-44&catid=18%3A2009-06-23-04-49-37&Itemid=21&lang=ru
Graviton-M – air gravimetric complex, AUSRI of Geophysics, SSPE “Aerogeofizika”, Bauman MSTU. http://geogk.ru/rus/geophis/grav/grav.shtml
Korobiichuk, I., Koval, A., Nowicki, M., Szewczyk, R.: Investigation of the effect of gravity anomalies on the precession motion of single gyroscope gravimeter. Solid State Phenom. 251, 139–145 (2016)
Karachun, V., Melnick, V., Korobiichuk, I., Nowicki, M., Szewczyk, R., Kobzar, S.: The additional error of inertial sensors induced by hypersonic flight conditions. Sensors (Switzerland) 16(3), 299 (2016). doi:10.3390/s16030299
Korobiichuk, I.: Mathematical model of precision sensor for an automatic weapons stabilizer system. Measure. J. Int. Measure. Confed. 89, 151–158 (2016). doi:10.1016/j.measurement.2016.04.017
Korobiichuk, I.: Analysis of errors of piezoelectric sensor of weapons stabilizer. Metrol. Meas. Syst. 1 (2017). doi:10.1515/mms-2017-0001
Korobiichuk, I., Ladanyuk, A., Shumyhai, D., Boyko, R., Reshetiuk, V., Kamiński, M.: How to increase efficiency of automatic control of complex plants by development and implementation of coordination control system. Adv. Intell. Syst. Comput. 543, 189–195 (2017). doi:10.1007/978-3-319-48923-0_23
Grabar, I., Korobiichuk, I., Petruk, O.: Torque and capacity measurement in rotating transmission. Adv. Intell. Syst. Comput. 543, 464–472 (2017). doi:10.1007/978-3-319-48923-0_49
Korobiichuk, I., Bezvesilna, O., Tkachuk, A., Nowicki, M., Szewczyk, R.: Piezoelectric gravimeter of the aviation gravimetric system. Adv. Intell. Syst. Comput. 440, 753–761 (2016). doi:10.1007/978-3-319-29357-8_65
Jentzsch, G., Schulz, R., Weise, A.: A well-known principle in a new gravimeter: the automated Burris gravity meter. AVN Allg. Vermess. Nachr. 122(5), 168–175 (2015)
Korobiichuk, I., Podchashinskiy, Y., Shapovalova, O., Shadura, V., Nowicki, M., Szewczyk, R.: Precision increase in automated digital image measurement systems of geometric values. In: Jabłoński, R., Brezina, T. (eds.) Advances in Intelligent Systems and Computing, vol. 393, pp. 335–340. Springer, Cham (2016). doi:10.1007/978-3-319-23923-1_51
Korobiichuk, I., Bezvesilna, O., Tkachuk, A., Chilchenko, T., Nowicki, M., Szewczyk, R.: Design of piezoelectric gravimeter for automated aviation gravimetric system. J. Autom. Mob. Robot. Intell. Syst. 10(1), 43–47 (2016). doi:10.14313/JAMRIS_1-2016/6
Bezvesilna, O.M.: Piezoelectric gravimeter of aviation gravimetric systems: monograph. Zhytomyr: ZSTU, 604 p. (2007)
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Bezvesilna, O., Kamiński, M. (2017). Gravimeters of Aviation Gravimetric System: Classification, Comparative Analysis, Prospects. In: Szewczyk, R., Zieliński, C., Kaliczyńska, M. (eds) Automation 2017. ICA 2017. Advances in Intelligent Systems and Computing, vol 550. Springer, Cham. https://doi.org/10.1007/978-3-319-54042-9_48
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DOI: https://doi.org/10.1007/978-3-319-54042-9_48
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