Abstract. The features of monitoring the state of rocket and space equipment (RCP), transported by rail, are analyzed. The questions of complex use of methods, technologies and means of navigational definitions are considered on the basis of combined navigation systems, including small-scale inertial-free modules with coordinate correction modules based on GLONASS/GPS signals. The developed experimental model of the hardware-software complex of multi-level wireless system for assessing the state of transported space objects is based on combination of navigation systems with telemetric means of measuring external factors affecting the transported RKT objects. Information about the state of the RCT facility is collected remotely by non-contact sensors with low power consumption. The sensors are integrated into a selforganizing wireless network using radio modules operating under the IEEE 802.15.4 ZigBee standard. This approach allows for the collection and transmission of information on the status of the monitored RCT facility at various levels of control and operational control in a near real time mode.

Keywords: object of rocket and space technology, self-organizing networks, transportation, control settings, external influencing factors, wireless and contactless sensors

References:

1. Zaychenko Yu.V., Ivanov A.S. Metodika kompleksnoy obrabotki dannykh o sostoyanii i koordinatakh ob”yektov kosmicheskoy tekhniki pri ikh transportirovanii (Methods of Complex Processing of Data on the State and Coordinates of Space Technology Objects during Their Transportation), Moscow, 2014, 28 р. (in Russ.)
2. Makarov S.M., Ivanov A.S. Otchet o NIR. Razrabotka tekhnicheskogo proyekta eksperimental’nogo obraztsa APK MBSO sostoyaniya ob”yektov KT i vozdeystvuyushchikh faktorov pri transportirovanii razlichnymi vidami transporta (Report on the Research Work. Development of a Technical Project of an Experimental Sample of a Hardware-Software Complex of a Multi-Level Wireless System for Assessing the State of Space Technology Objects and the Factors Influencing the Transportation by Various Modes of Transport), Moscow, 2014, 225 р. (in Russ.)
3. IEEE standard 802.15.4d – 2009.
4. Akyildiz I.F., Su W., Sankarasubramaniam Y., Cayirci E. Computer Networks, 2002, no. 38, pp. 393–422. 
5. Erkin A. Wireless Technologies, 2010, no. 2, pp. 20–24. (in Russ.)
6. Sukun Kim. Wireless Sensor Networks for Structural Health Monitoring, Master’s thesis, U.C. Berkeley, 2005, рр. 24–45.
7. Panfilov D., Sokolov M. Electronic Components, 2004, no. 12, pp. 35–55. (in Russ.)
8. Barash L. Komp’yuternoye obozreniye, 2003, no. 10, pp. 8–12. (in Russ.)
9. Pushkarev O. Novosti Elektroniki, 2007, no. 16, pp. 22–34. (in Russ.)
10. Korkishko Yu.N., Fedorov V.A., Prilutskiy V.E., Ponomarev V.G., Morev I.V., Skripnikov S.F., Khmelevskaya M.I., Buravlev A.S., Kostritskiy S.M., Zuyev A.I., Varnakov V.K. Giroskopiya i navigatsiya. ХХ Sankt-Peterburgskaya mezhdunarodnaya konferentsiya po integrirovannym navigatsionnym sistemam (Gyroscopy and Navigation. XX St. Petersburg International Conference on Integrated Navigation Systems), Moscow, 2014, рр. 16–24. (in Russ.)
11. Volovich G.V., Volovich A.V. Components & Technologies, 2002, no. 1, pp. 66–72. (in Russ.)
12. Asch G et al. Les capteurs en instrumentation industrielle, 2010, 880 р.
13. Gudinaf F. Elektronika, 1993, no. 7–8, pp. 54–57. (in Russ.)
14. Gudinaf F. Elektronika, 1993, no. 11, pp. 86–87. (in Russ.)