Cryogenic sensor for gravimetric devices

1Cheborin, OG, 1Yatsenko, VA
1Space Research Institute of the National Academy of Sciences of Ukraine and the State Space Agency of Ukraine, Kyiv, Ukraine
Kosm. nauka tehnol. 1998, 4 ;(5):129–140
https://doi.org/10.15407/knit1998.05.129
Section: Space Instruments
Publication Language: Russian
Abstract: 
Certain results of theoretical investigations are considered for their application to the creation of a highly sensitive superconducting gravity sensor. We have studied the mathematical model of the sensor, the dynamics and equilibrium of the sensitive element, and its design. Algorithms are proposed for the preprocessing and filtration of signals.
Keywords: cryogenic sensor, preprocessing and filtration of signals, space instruments
References: 
1. Braginskii V. B. Physical Experiments with Test Bodies, 136 p. (Nauka, Moscow, 1970) [in Russian].
2. Butkovski A. G., Samoylenko Yu. I. Control of Quantum-Mechanics Processes, 256 p. (Nauka, Moscow, 1984) [in Russian].
3. Verkin B. N., Mende F. F., Trubicin A. V., et al. superconducting gravimeter. Materials All-Union. ings of the Conference. on Low Temperature Physics: abstracts, Kiev, 1974, 237—238 (Nauk. dumka, Kiev, 1974) [in Russian].
4.  Verjaskin A. V., Krysanov V. A., Monahov E. A. The superconducting gravity meter for precise gravity inertial measurements. In: Modern theoretical and experimental problems of relativity and gravitation theory, P. 280 (Moscow, 1984) [in Russian].
5. Wick G.-C. The Extention of Measurement. Uspehi fiz. nauk, 101 (2), 303—329 (1970) [in Russian].
6. Mudretsova E. A. (Ed.) Gravity. Directory of Geophysics, 320 p. (Nedra, Moscow, 1990) [in Russian].
7. Didenko A. P., Samojlenko G. M., Kuznetsov S. I. Cryogenic gravimeter. In: Metrology in gravimetry, 65—66 (Kharkov, 1980) [in Russian].
8. Maslov I. A. (Ed.) Long term stability of gravimetric and inertial instruments, 120 p. (Nauka, Moscow, 1979) [In Russian].
9. Zagarii G. I., Shubladze A. M. Control Systems Synthesis on the Basis of Maximum Stability Degree Criterion, 104 p. (Energoatomisdat, Moscow, 1988) [In Russian].
10. Kalman R. E., Falb P. L., Arbib M. A. Topics in mathematical system theory, 400 p. (Mir, Moscow, 1981) [In Russian].
11. Knopov P. S., Yatsenko V. A. Estimation of unknown parameters of an almost periodic signal from controlled bilinear observations. Avtomat. i Telemekh., No. 3, 65—73 (1992) [In Russian].
12. Kozorez V. V., Kolodeev I. D., Kryukov M. I., et al. On potential well of magnetic  interaction of ideal current loops. Dokl. Akad. Nauk Ukr. SSR, Ser. A., No. 3, 248-249 (1976) [In Russian].
13. Kozorez V. V. Cheborin O. G. On stability of equilibrium in a system of two ideal current rings. Dokl. Akad. Nauk UkrSSR, Ser. A,
No. 1, 80—81 (1977) [In Russian].
14. Kozorez V., Yatsenko V. Differential-geometrical methods of analysis of nonlinear controlled circuits with a Josephson junction. In: Int. Conf. Theor. Electrical Engineering:  Abstracts, 87—88 (Nauka, Moscow, 1985) [in Russian].
15. Kukhtenko A. I. Problem of Invariance in Automation, 376 p. (Gostekhizdat USSR, Kiev, 1963) [in Russian].
16. Levitskaya Z. P. The theoretical model of inertial premises-hee in aero gravimetry. In: Gravity and magnetic studies, 50—59 (Moscow, 1989) [in Russian].
17. Likharev K. K., Ulrich B. T. Systems with Josephson junctions - Theoretical principles, 447 p.          (Izdatel'stvo Moskovskogo Universiteta, Moscow, 1978) [In Russian].
18. Malkin I. G. Theory of Motion Stability, 240 p. (Fizmatgiz, Moscow, 1966) [In Russian].
19. Menskii M. B. Group of paths: Measurements, fields, particles, 320 p. (Nauka, Moscow, 1983) [In Russian].
20. Mikhalevich V. S., Kozorez V. V., Rashkovan V. M., et al. Magnetic Potential Well: The Effect of Stabilization of Dynamic Superconducting Systems, 335 p. (Naukova Dumka, Kiev, 1991) [in Russian].
21. Panteleev V. L. On the problem of measuring the force of gravity on board the aircraft. In: Gravity and magnetic studies, P. 60 (Moscow, 1989) [In Russian].
22. Pars L. A. A Treatise on Analytical Dynamics, 636 p. (Nauka, Moscow, 1971) [In Russian].
23. Repeated gravity observations: The results of theoretical research and observations at landfills, 133 p. (Coll. scientific. Materials of the  Interdepartmental Geophysical. Committee of the Presidium of the Academy of Sciences of the USSR) (Moscow, 1983) [In Russian].
24. Repeated gravity observations: Theory and results, 143 p. (Coll. Sci. Mat. VNIIGeofizika) (Moscow, 1984) [In Russian].
25. Popov E. I. Determination of gravity on the movable base, 218 p. (Nauka, Moscow, 1967) [in Russian].
26. Popov E. I., Kochetkov B. M. The elastic system of marine gravimeter. In: Instrumental and experimental-methodological work on marine gravimetry, 6—32 (Nauka, Moscow, 1973) [in Russian].
27. Rose-Innes A. C., Rhoderick E. H. Introduction to superconductivity, 272 p. (Mir, Moscow, 1972) [in Russian].
28. Cheborin O. G. Mathematical model of sensor of gravity-inertial devices. Cybernetics and computer engineering, Is. 103, 89—96 (1994) [in Russian].
29. Yatsenko V. A. Estimating the signal acting on a macroscopic body in a controlled potential well. Kibernetika, No. 2, 81—85 (1989) [in Russian].
https://doi.org/10.1007/bf01070133
30. Yatsenko V. A. Filtering and processing methods biomagnit¬nyh signals under the influence of noise factors: Preprint, AN USSR, V. M. Glushkov  InstituteCybernetics; No. 91-9, 25 p. (Kiev, 1991) [in Russian].
31. Fujimoto H., Tomoda Y. Superconducting gravimeter of novel design. J. Geod. Soc. Jap., 26 (2), 75—81 (1980).
32. Nakagawa Ichiro (Ed.) et al. Proceeding of the General Meeting of the International Associa­tion of Geodesy (Tokyo, May 7—15, 1982), Kyoto; Local Organ Comm. Gen. Meet., 734 p. (IAG, 1982).
33. Prothero W., Goodkind J. Superconducting gravimeter. Rev. Sci. Instrum., 39 (9), 1257—1262 (1968).
https://doi.org/10.1063/1.1683645

34. Tuman V. Cryogenic gravity meter. Proc.  12-th Int. Conf. Low Temp. Phys., Kyoto,  1970, 859—861 (Tokyo, 1971).