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Transcription:

621.396 DOI: 10.26467/2079-0619-2017-20-5-43-49,.. 1 1,., - ( ), I, - II III,.,., ( ),,,, -.,, -,. -,.. :,,, -,. [1, 2]. - : - ( ), -, -., - ( ) -, - -,,,., -,., [1, 8], [5, 7]. 43

20, 05, 2017., [9, 10] ( ), (1), -,, H - ( - ).. 2 :. 1., [5, 7]., -,., -,. N - ( ) X_(1..N), -. - -,., (2), N,, M, 1..M.., (3),, -. -,, ( ), ( ). -,. -,,... (4) 44

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,,, -. - [6] 0,1.. 1. Values of errors at influence of the reflected signals 1 Table 1 - > 30 3,5 0,1 14,4 1,09 1 0.9 0.8 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0-1 -0.8-0.6-0.4-0.2 0 0.2 0.4 0.6 0.8 1,.. 1. ( ), Fig. 1. Comparison of the shape of the GLONASS PT signal correlation function (CF), distorted by echo impact with the shape of the CF after beamforming 8,. -,, -, -. -, -,. [3]., -,, - - - [1, 2]. 47

20, 05, 2017. 1.. /...,... 4-.,...:, 2010. 800. 2. Kaplan E.D., Hegarty C.J. Understanding GPS. Principles and Applications, ARTECH HOUSE, 2006, 703 p. 3.....: -, 2000. 270 c. 4. Sgammini M., Antreich F., Kurz L., Meurer M., Noll T.G. Blind Adaptive Beamformer Based on Orthogonal Projections for GNSS. 25th International Technical Meeting of the Satellite Division of The iinstitute of Navigation, Nashville TN, September 17 21, 2012, p. 925 936. 5. Ying Chieh (Jay) Chuang, Inder J. Gupta. Two stage beamformer for GNSS receiver antenna arrays. Proceedings of the 27th International Technical Meeting of the ION Satellite Division. ION GNSS+ 2014. Tampa. Florida. September 8 12. 2014, p. 2277 2285. 6. Parkinson B.W., Spilker J.J. (Eds.). Global Positioning System: Theory and Applications. Volume I and II. Published by the American Institute of Aeronautics and Astronautics, Inc. 370 L Enfant Promenade, SW, Washington, DC 20024-2518. 1996. 7. Hattich C., Cuntz M., Konovaltsev A., Kappen G., Meurer M. Robust Multi-Antenna Acquisition in Time, Frequency and Space for a Digital Beamforming Receiver. 24th International Technical Meeting of the Satellite Division of The Institute of Navigation. September 19 23, 2011, p. 724 731. 8...,.. - //. 2008. 7.. 45 50. 9...,.. : :...:, 1986. 448. 10. Harry L. Van Trees. Optimum Array Processing. Part IV of Detection, Estimation and Modulation Theory. Wiley-Interscience, 2002, 1443 p. 11...,.. - «/» // -. 2017. 2.. 11 16., «, KrinitskiGV@mail.ru. THE SIGNALS TREATMENT ALGORITHM FOR SATELLITE RADIO NAVIGATIONAL EQUIPMENT CONSUMERS INTENDED TO PROVIDE A PRECISION APPROACH TO THE RUNWAY IN CONDITIONS OF RADIO INTERFERENCE IMMUNITY Georgy V. Krinitskiy 1 1 Moscow Design Bureau Compas, Moscow, Russia ABSTRACT Currently, a number of countries widely implemented the landing aircraft system according to the signals of satellite navigation systems (SNS), providing the approach for category I, and the research and development in the area of improvement to ensure the approach categories II and III are actively conducted, they impose higher requirements on such characteris- 48

tics as accuracy and reliability. An approach to the runway and landing are very crucial stages of flight, therefore, the necessity of high reliability landing systems are required with the help of SNS signals. Due to the fact that the SNS consumer equipment interference immunity (SNS CE), in which there are no special measures for protection from noise and the provision of maintenance at low levels of the received signals is extremely low, so the navigational equipment is becoming easy targets for terrorist, sabotage and vandalism actions due to its simplicity and compactness of the device jamming for SNS. In addition, due to the continuous expansion of the use of various radio communication facilities, the risk of emergence of the interference immunity of the SNS consumer equipment increases, caused by spurious emissions of radio communication means during their operation or as a result of their disfunction. The algorithm of signals treatment in ground and onboard radio navigational equipment designed to ensure a precise landing approach with the help of SNS signals is suggested. The mathematical modeling of the algorithm during the conditions of signals multipath distribution was held. Key words: satellite navigation system, approach, interference immunity protection, multipath, adaptive antenna system. REFERENCES 1. Perov A.I., Harisov V.N. GLONASS. Printsipy postroyeniya i funktsionirovaniya [GLONASS. Principles of construction and operation]. ed. 4th, revised. and additional. Moscow, Radiotehnika, 2010, 800 p. (in Russian) 2. Kaplan E.D., Hegarty C.J. Understanding GPS. Principles and Applications, ARTECH HOUSE, 2006, 703 p. 3. Solov'yev Yu.A. Sistemy sputnikovoy navigatsii [Satellite navigation systems]. oscow, ECO-TRENDS, 2000, 270 p. (in Russian) 4. Matteo Sgammini, Felix Antreich, Lothar Kurz, Michael Meurer, Tobias G. Noll. Blind Adaptive Beamformer Based on Orthogonal Projections for GNSS. 25th International Technical Meeting of the Satellite Division of The iinstitute of Navigation, Nashville TN, September 17 21, 2012, pp. 925 936. 5. Ying Chieh (Jay) Chuang, Inder J. Gupta. Two stage beamformer for GNSS receiver antenna arrays. Proceedings of the 27th International Technical Meeting of the ION Satellite Division. ION GNSS+ 2014. Tampa. Florida. September 8 12. 2014, pp. 2277 2285. 6. Parkinson B.W., Spilker J.J. (Eds.). Global Positioning System: Theory and Applications. Volume I and II. Published by the American Institute of Aeronautics and Astronautics, Inc. 370 L Enfant Promenade, SW, Washington, DC 20024-2518. 1996. 7. Hattich C., Cuntz M., Konovaltsev A., Kappen G., Meurer M. Robust Multi-Antenna Acquisition in Time, Frequency and Space for a Digital Beamforming Receiver. 24th International Technical Meeting of the Satellite Division of The Institute of Navigation. September 19 23, 2011, pp. 724 731. 8. Yefimenko V.S., Kharisov V.N. Adaptivnyye formirovateli luchey dlya povysheniya pomekhoustoychivosti priyemnikov SRNS [Adaptive beam formers for improving the noise immunity of SRNS receivers]. Radiotehnika, 2008, 7, pp. 45 50. 9. Harry L. Van Trees. Optimum Array Processing. Part IV of Detection, Estimation and Modulation Theory. Wiley-Interscience, 2002, 1443 p. 10. Karpinskiy K.Yu., Ognev V.A. Rezul'taty sravneniya razlichnykh variantov postroyeniya NAP dlya vysokodinamichnykh ob"yektov pri nizkikh sootnosheniyakh «signal/shum» [Results of comparison of variants of navigation equipment architectures for highly dynamic objects at low signal-tonoise ratios]. Novosti navigatsii, 2017, 2, pp. 11 16. INFORMATION ABOUT THE AUTHOR Georgy V. Krinitskiy, Head of Development Department of JSC MDB Compas. KrinitskiGV@mail.ru. 01.09.2017 Received 01.09.2017 20.09.2017 Accepted for publication 20.09.2017 49

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