REDUNDANCY IN TDOA METHOD OF AIRCRAFT POSITION ESTIMATION

The paper deals with the main methods for solving equations with redundancy. It is subsequently used for modelling the ground many-positional system as a part of a system for analysis of air navigation data as a whole. In particular, the least square method and the Taylor series method are modelled taking into account the impact of stochastic factors influencing the system output. The factors with maximal effect on the accuracy of the functioning of the ground many-positional system are determined; a comparative analysis of the methods is carried on.

ADS-B, TDOA, Information Security, Least Squares, Taylor series

1. The concept of creation and development of Russian Air Navigation System (approved at a government meeting on October 4, 2006). URL: www.atminst.ru/upfiles/concept.pdf

2. The concept of modernization and development of the Unified Air Traffic Management System of the Russian Federation (approved on February 22, 2000. № 144). URL: www.consultant.ru/document/consdoc_LAW_26256

3. Identification of ADS-B system vulnerabilities and threats, Australasian Transport Research Forum 2010 Proceedings, 29 September – 1 October 2010.

4. Exploring potential ads-b vulnerabilites in the FAA’s nextgen air transportation system, Donald L. McCallie, Major, USAF AFIT/ICW/ENG/11-09, 2011.

5. Costin A. Ghost in the Air (Traffic): On insecurity of ADS-B protocol and practical attacks on ADS-B devices. Aur´elien Francillon, EURECOM, 2012.

6. Smith A., Cassell R., Breen T., Hulstrom R., Evers C. Methods to provide system-wide ADS-B back-up, validation and security. Rannoch Corporation, Alexandria, VA, 25th Digital Avionics Systems Conference, IEEE, October 15, 2006.

7. Yang K., An J., Xu Zh. A Quadratic Constraint Total Least-squares Algorithm for Hyperbolic Location. I.J. Communications, Network and System Sciences. 2008. Vol. 2. Pp. 105-206.

8. Aatique M. Evaluation of TDOA techniques for position location in CDMA systems. Virginia Polytechnic Institute and State University, September 1997.

9. Chan Y.T. A Simple and Efficient Estimator for Hyperbolic Location. IEEE Transactions on signal processing. Vol. 42. No. 8. August 1994.

10. Kovell B. А Comparative Analysis of ADS-B Verification Techniques. University of Colorado, 2014.

11. Foy W.H. Position-location solutions by Taylor-series estimation. IEEE Transactions on Aerospace and Electronic Systems. 1976. Vol. 12. No. 2. Pp. 187–194.

12. Smith J.O., Abel J.S. Closed-form least-squares source location estimation from rangedifference measurements. IEEE Transactions on Acoustics, Speech, and Signal Processing. Vol. 35. No. 12. Pp. 1661–1669. 1987.

13. Manual on Implementation of a 300m (1 000 ft) Vertical Separation Minimum Between FL 290 and FL 410 Inclusive, Doc 9574, ICAO, Second Edition – 2001.

14. Guidance Material on Comparison of Surveillance Technologies (GMST), ICAO, Edition 1.0 – September 2007.

15. http://navis.ru/ru/katalog/grazhdanskoe-naznachenie/vremennaya-sinhronizaciya/sn-5831 – Design office NAVIS navigation systems.

16. Luong V.Ch. Hybrid algorithms estimating the coordinates of the radio source with the fixed and mobile collection points, thesis for the degree of candidate of technical sciences. Ryazan: Ryazan State Radio Engineering University, 2014.

17. Federal Rules of using the airspace of the Russian Federation, Resolution of the Government of the Russian Federation N 138, March 11, 2010, Moscow. URL: www.consultant.ru/document/cons_doc_LAW_98957