Abstract
Strapdown inertial navigation systems (SINS) are basic parts of modern integrated navigation systems in various vehicles. Currently, fiber-optic gyroscopes (FOGs) with closed-loop feedback are finding increasing use for inertial navigation systems. The paper presents SINS-500K, SINS-500M and SINS-501 developed and produced by the Russian Research & Production Company Optolink with Optolink FOGs. The test results are discussed. Optolink FOGs and SINS’s are compared with similar devices of world leading manufacturers.
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References
Titterton, D. and Weston, J., Strapdown Inertial Navigation Technology, Institution of Engineering and Technology, 2005.
Lawrence, A., Modern Inertial Technology: Navigation, Guidance, and Control, Springer, 2012.
Chatfield, A.B., Fundamentals of High Accuracy Inertial Navigation, AIAA, 1997.
Noureldin, A., Karamat, T.B., and Georgy, J., Fundamentals of Inertial Navigation, Satellite-based Positioning and their Integration, Springer, 2013.
Anuchin, O.N. and Emel’yantsev, G.I., Integrirovannye sistemy orientatsii i navigatsii (BINS i BISO) (Integrated systems of Orientation and Navigation), Peshekhonov, V.G., Ed., St. Petersburg: TsNII Elektropribor, 1999.
Matveev, V.V. and Raspopov, V.Ya., Osnovy postroeniya besplatformennykh inertsial’nykh navigatsionnykh sistem (Design Fundamentals of Strapdown Inertial Navigation Systems), St. Petersburg: TsNII Elektropribor, 2009.
Sokolov, S.V. and Pogorelov, V.A., Osnovy sinteza mnogostrukturnykh besplatformennykh inertsial’nykh navigatsionnykh sistem (Synthesis Basics of Multistructural Strapdown Inertial Navigation Systems), Moscow: Fizmatlit, 2009.
Meleshko, V.V. and Nesterenko O.I., Besplatformennye inertsial’nye navigatsionnye sistemy (Strapdown Inertial Navigation Systems), Kirovograd: Polimed-Servis, 2011.
Barbour, N. and Schmidt, G., Inertial sensor technology trends, Giroskopiya i Navigatsiya, 2000, no. 1, pp. 3–13.
Peshekhonov, V.G., Gyroscopic navigation systems: Current status and prospects, Gyroscopy and Navigation, 2011, vol. 2, no. 3, pp. 11–118.
Lefevre H., The Fiber-Optic Gyroscope, Artech House, 1993.
Optical Fiber Rotation Sensing, Burns, W.K., Ed., Academic Press, 1994.
Velikosel’tsev, A.A. and Filatov, Yu., V., Volokonnoopticheskie tekhnologii v navigatsionnykh sistemakh: Uchebnoe posobie (Fiber-Optic Technologies in Navigation Systems: Tutorial), St. Petersburg: Izd. SPb-GETU LETI, 2011.
Luk’yanov, D.P., Laser and fiber-optic gyroscopes: Current status and prospects, Giroskopiya i Navigatsiya, 1998, no. 4, pp. 20–45.
Lefevre, H.C., The fiber-optic gyroscope: Achievement and perspective, Gyroscopy and Navigation, 2012, no. 4, pp. 223–226.
http://www.northropgrumman.com/Capabilities/NavigationSystems/Pages/default.aspx, J.M. Strus, M. Kirkpatrick, J. Sinko. GPS/IMU development of a high accuracy pointing system for maneuvering platforms // Inside GNSS, 2008. N3, p.30–37.
http://www.honeywell.com/sites/aero/Inertial_Navigation_Products
http://www.kvh.com/Military-and-Government/Gyros-and-Inertial-Systems-and-Compasses.aspx
Logozinskii V., Safutin I., and Solomatin, V., A fiber-optic rotation sensor with corrected digital output, Giroskopiya i Navigatsiya, 2002, no. 3, pp. 93–102.
Kolevatov, A.P., Nikolaev, S.G., Andreev, A.G., Ermakov, V.S., Kel’, O.L., and Shevtsov D.I., Fiber-optic gyroscope of navigation-grade strapdown inertial systems. Development, temperature compensation, and tests, Giroskopiya i Navigatsiya, 2010, no. 3, pp. 49–60.
Meshkovskii, I.K., Strigalev V.E., Deineka, G.B., Peshekhonov, V.G., and Nesenyuk L.P., Three-axis fiber-optic gyroscope for marine navigation systems, Giroskopiya i Navigatsiya, 2009, no. 3, pp. 3–9.
Meshkovskii, I.K., Strigalev V.E., Deineka, G.B., Peshekhonov, V.G., Volynskii, D.B., and Untiliv, A.A., Three-axis fiber-optic gyroscope. The results of the development and preliminary tests, Giroskopiya i Navigatsiya, 2011, no. 3, pp. 67–74.
Korkishko, Yu.N., Fedorov, V.A., Prilutskii, V.E., Ponomarev, V.G., Fenyuk, M.A., Marchuk, V.G., Kostritskii, S.M., and Paderin, E.M., High-precision fiber-optic gyroscope with a linear digital output, Giroskopiya i Navigatsiya, 2004, no. 1, pp. 69–82.
Prilutskii, V.E., Ponomarev, V.G., Marchuk, V.G, Fenyuk, M.A., Korkishko, Yu.N., Fedorov, V.A., Kostritskii, S.M., Kostritskii, S.M., Paderin, E.M., and Zuev A.I., Interferometric fiber-optic gyroscopes with a linear digital output, Giroskopiya i Navigatsiya, 2004, no. 3, pp. 62–72.
Korkishko, Yu.N., Fedorov, V.A., Prilutskii, V.E., Ponomarev, V.G., Marchuk, V.G., Morev, I.V., Paderin, E.M., Kostritskii, S.M., Branets, V.N., and Ryzhkov, V.S., Space-grade three-axis fiber-optical gyroscope, Proc. EOS Topical Meeting on Photonic Devices in Space, October 18–19, 2006, Paris, France, vol.5, pp. 32–35.
Korkishko, Yu.N., Fedorov, V.A., Prilutskii, V.E., Ponomarev, V.G., Morev, I.V., Marchuk, V.G, Kostritskii, S.M., and Paderin, E.M., Interferometric fiber-optic gyroscopes, Foton-Ekspress, 2007, 6(62), pp. 47–49.
Korkishko, Yu.N., Fedorov, V.A., Prilutskii, V.E., Ponomarev, V.G., Marchuk, V.G., Morev, I.V., Paderin, E.M., Kostritskii, S.M., Paderin, Nesenyuk, L.P., Buravlev, A.S., and Lisin, L.G., Navigation-grade fiber-optical gyroscope, Giroskopiya i Navigatsiya, 2008, no. 1, pp.71–81.
Korkishko, Yu.N., Fedorov, V.A., Prilutskii, V.E., Ponomarev, V.G., Morev, I.V., and Kostritskii, S.M., Interferometric closed-loop fiber-optic gyroscopes, Proc. SPIE, vol. 8351, Third Asia Pacific Optical Sensors Conference, John Canning, Gangding Peng, Eds., (SPIE, Bellingham, WA, 2012), 83513L, pp. 83513L-1–83513L-8 (2012).
Korkishko, Yu.N., Fedorov, V.A., Prilutskii, V.E., Ponomarev, V.G., Morev, I.V., Kostritskii, S.M., Zuev, A.I., and Varnakov, V.K., Closed-loop fiber-optical gyroscopes for commercial and space applications, Proc. Inertial Sensors and Systems, Symposium Gyro Technology 2012, Karlsruhe, Germany, 18–19 September 2012, pp. 14.1–14.15.
Korkishko, Yu.N., Fedorov, V.A., Prilutskii, V.E., Ponomarev, V.G., Morev, I.V., Kostritskii, S.M., Zuev, A.I., and Varnakov, V.K., Interferometric closed-loop fiber-optical gyroscopes for commercial and space applications, Proc. SPIE, vol. 8421, OFS2012 22nd Int. Conf. on Optical Fiber Sensors, Yanbiao Liao, Wei Jin, David D. Sampson, Ryozo Yamauchi, Youngjo Chung, Kentaro Nakamura, Yunjiang Rao, Eds., (SPIE, Bellingham, WA, 2012), 842107, pp. 842107-1–842107-8 (2012).
Korkishko, Yu.N., Fedorov, V.A., Prilutskii, V.E., Ponomarev, V.G., Morev, I.V., Obuhovich, D.V., Fedorov I.V., and Krobka, N.I. Investigation and identification of noise sources of high precision fiber optic gyroscopes, 20 th St. Petersburg Int. Conf. on Integrated Navigation Systems, St. Petersburg: Elektropribor, 2013, pp. 59–62.
Korkishko, Yu.N., Fedorov, V.A., Prilutskii, V.E., Plotnikov, P.K., Mikheev, À.V., and Naumov, S.G., Study of SINS Work in the Conditions of the High Latitudes Taking into Account the Real Sensors Errors. 16th St. Petersburg Int. Conf. on Integrated Navigation Systems, St. Petersburg: Elektropribor, 2009, pp. 58–61.
Korkishko, Yu.N., Fedorov, V.A., Prilutskii, V.E., Chernodarov., A.V., Matyushkin., V.A., and Perelyaev, S.E., An object-oriented technology for the integration of navigation sensors and its implementation in the SINS-1000 strapdown inertial system built around fiber-optic gyros, 16th St. Petersburg Int. Conf. on Integrated Navigation Systems, St. Petersburg: Elektropribor, 2009, pp. 18–27.
Chernodarov, A.V., Patrikeev, A.P., Korkishko, Yu.N., Fedorov, V.A., and Perelyaev, S.E., Software Seminatural Development for FOG Inertial Satellite Navigation System SINS-500, Gyroscopy and Navigation, 2010, vol. 1, no. 4, pp. 330–340.
Korkishko, Yu.N., Fedorov, V.A., Kostritskii, S.M., Alkaev, A.N., Paderin, E.M., Maslennikov, E.I., and Apraksin, D.V., Multifunctional integrated optical chip for fiber optical gyroscope fabricated by high temperature proton exchange, Proc. SPIE, vol. 4944, Integrated Optical Devices: Fabrication and Testing, Giancarlo C. Righini, Ed., (SPIE, Bellingham, WA, 2003), pp. 262–267.
Korkishko, Yu.N., Fedorov, V.A., Prilutskii, V.E., Ponomarev, V.G., Morev, I.V., Kostritskii, S.M., Zuev, A.I., and Varnakov, V.K., Optimization of multi-function integrated optics chip fabricated by proton exchange in LiNbO3, Proc. SPIE, vol. 9065, Fundamentals of Laser-Assisted Micro- and Nanotechnologies 2013, 90650E (November 28, 2013). (doi:10.1117/12.2051638).
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Published in Russian in Giroskopiya i Navigatsiya, 2014, No. 1, pp. 14–25.
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Korkishko, Y.N., Fedorov, V.A., Prilutskii, V.E. et al. Strapdown inertial navigation systems based on fiber-optic gyroscopes. Gyroscopy Navig. 5, 195–204 (2014). https://doi.org/10.1134/S2075108714040154
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DOI: https://doi.org/10.1134/S2075108714040154