Abstract
The paper focuses on enhancing the thermal stability (reducing the temperature differences) in fiber-optic gyros and accelerometers within a strapdown inertial navigation system by applying nanostructure composite materials based on carbon nanotubes with high thermal conductivity.
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Korkishko, Yu.N., Fedorov, V.A., Prilutskii, V.E., Ponomarev, V.G., Morev, I.V., Skripnikov, S.F. et al., Strapdown inertial navigation systems based on fiberoptic gyros, Giroskopiya i Navigatsiya, 2014, no. 1 (84), pp. 14–25.
Sheremet’ev, A.G., Volokonnyi opticheskii giroskop (Fiber-Optic Gyro), Moscow: Radio i Svyaz, 1987.
Vakhrameev, E.I., Galyagin, K.S., Kiselev, E.V., Oshivalov, M.A., and Ulrikh, T.A., Thermal drift of fiber-optic gyro, Priborostroenie, 2011, no. 1, pp. 32–37.
Dzhashitov, V.E. and Pankratov, V.M., Datchiki, pribory i sistemy aviakosmicheskogo i morskogo priborostroeniya v usloviyakh morskikh vozdeistvii (Sensors, Devices and Systems for Aerospace and Marine Instrumentation under Thermal Effects), Peshekhonov, V.G., Ed., St. Petersburg, CSRI Elektropribor, 2005.
Dzhashitov, V.E., Pankratov, V.M., Golikov, A.V., Gubanov, A.G., and Efremov, M.V., Reducing thermal sensitivity of fiber-optic gyros, Giroskopiya i Navigatsiya, 2011, no. 4 (75), pp. 42–56.
Kolevatov, A.P., Nikoleav, S.G., Andreev, A.G., Ermakov, V.S. at al., Progress in development of strapdown inertial navigations systems on fiber-optic gyroscopes, 16th St. Petersburg International Conference on Integrated Navigation Systems, CSRI Elektropribor, 2009, pp. 12–17.
Sushchenko, O.A. and Pal’chik, V.V., Overview of current state of fiber-optic angular senor technology and development trends, Elektronika i Sistemy Upravleniya, 2011, no. 3(29), pp. 74–84.
Dzhashitov, V.E., Pankratov, V.M., Golikov, A.V., Nikolaev, S.G., Kolevatov, A.P., Plonikov, A.D., and Koffer, K.V., Hierarchical thermal models of strapdown inertial navigation systems with FOGs and accelerometers, Giroskopiya i Navigatsiya, 2013, no. 1 (80), pp. 49–63.
Quatraro, E., Pizzarulli, A., Catasta, M., Crescenti, G., Spinozzi, E., and Cingolani, A., High performance FOG for non-temperature stabilized environment, Inertial Sensors and Systems–Symposium Gyro Technology, 20–21 September, 2011, Karlsrue, Germany.
Li, Zh., Meng, Zh., Liu, T., and Yao, X.S., A novel method for determining and improving the quality of a quadrupolar fiber gyro coil under temperature variations, OPTICS EXPRESS, 2013, 2521, vol. 21, no.2.
Blin, S., Kim, H.K., Digonnet, M.J.F., and Kino, G.S., Reduced thermal sensitivity of a fiberoptic gyroscope using an air-core photonic-bandgap fiber, J. Lightwave Technol., 2007, 25, no. 3, pp. 861–865.
Nanotechnology Research Directions: Vision for Nanotechnology in the Next Decade, Roko, M.C., Williams, R.S., and Alivisatos, P., Eds., New York: Springer, 2000.
Rakov, E.G., Nanotrubki i fullereny: uchebnoe posobie (Nanotubes and Fullerenes: A Manual), Moscow: Universitetskaya kniga, Logos, 2006.
OAO NPK Russkaya radioelektronika, Makhachkala, http://rre.su/projects/nano.html.
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Original Russian Text © A.V. Golikov, V.M. Pankratov, E.V. Pankratova, 2016, published in Giroskopiya i Navigatsiya, 2016, No. 2, pp. 33–40.
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Golikov, A.V., Pankratov, V.M. & Pankratova, E.V. Passive methods of enhancing thermal stability of nanostructured fiber-optic gyros. Gyroscopy Navig. 8, 38–42 (2017). https://doi.org/10.1134/S2075108716040039
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DOI: https://doi.org/10.1134/S2075108716040039