Synthesis and investigation of filtering algorithms used in the secondary processing of radar information
| Authors: Zinova V.V. |  |
| Published in issue: #8(25)/2018 | |
| DOI: 10.18698/2541-8009-2018-8-361 | |
Category: Informatics, Computer Engineering and Control | Chapter: System Analysis, Control, and Information Processing, Statistics |
|
Keywords: classic Kalman filter, alpha-beta filter, advanced Kalman filter, secondary processing, filtering algorithm, trajectory processing, dynamic system, simulation modeling, criterion of optimality, motion mode |
|
| Published: 09.08.2018 | |
The article provides a brief overview of the filtering algorithms used in the secondary processing of radar information in radar systems. To do this, simulation is performed, consisting of two stages. At the first stage, the mathematical model of the aircraft is built, and on the second stage, an experiment is carried out. During the experiment, three filtering algorithms are synthesized: the classic Kalman filter, the advanced Kalman filter, and the alpha-beta filter. The relationship between them and the principal differences is established. In the end, the conclusions in the form of recommendations on the feasibility and appropriateness of the application of the listed filtering algorithms in various air conditions are made.
References
[1] Panasyuk Yu.N., Pudovkin A.P. Obrabotka radiolokatsionnoy informatsii v radiotekhnicheskikh sistemakh [Radiolocation information processing in radiotechnical systems]. Tambov, TSTU publ., 2016, 84 p.
[2] Chervakov V.O., Bogdanov A.V., Zhironkin S.B. Science-methodical apparatus for synthesis of optimum measurement identification algorithms for state vectors of moving objects by means of different tracking systems based on filtration theory of discrete-continuous Markov processes. Inzhenernyy vestnik [Engineering Bulletin], 2016, no. 3. Available at: http://engsi.ru/doc/834362.html.
[3] Kuz’min S.Z. Tsifrovaya radiolokatsiya. Vvedenie v teoriyu [Digital radiolocation. Theory introduction]. Kiev, Kvits publ., 2000, 428 p.
[4] Zhironkin S.B., Chervakov V.O. Primenenie statisticheskikh metodov v aviatsionnykh radiolokatsionnykh kompleksakh [Application of statistical methods in aircraft radiolocation complexes]. LAP Lambert publ., 2012, 104 p.
[5] Fedorov I.B., ed. Informatsionnye tekhnologii v radiotekhnicheskikh sistemakh [Information technologies in radio-technical systems]. Moscow, Bauman MSTU publ., 2011, 846 p.
[6] Shakhtarin B.I. Fil’try Vinera i Kalmana [Viner and Kalman filters]. Moscow, Goryachaya liniya-Telekom publ., 2016, 396 p.
[7] Shakhtarin B.I., Suchkov V.B., Gubanov D.A. Optimal’naya fil’tratsiya sluchaynykh protsessov [Optimum filtration of random processes]. Moscow, Goryachaya liniya-Telekom publ., 2018, 90 p.
[8] Blair W.D. Fixed-gain two-stage estimators for tracking maneuvering targets. Naval Surface Warfare Center, 1992, 68 p.
[9] Nguen Chong Lyu. Issledovanie algoritmov soprovozhdeniya vozdushnykh tseley. Diss. kand. tekhn. nauk [Research on air target tracking algorithms. Kand. Tech. sci. diss.]. Moscow, MAI publ., 2004, 114 p.
[10] Zyuzin A.V., Turov V.E., Beloborodov A.V., Zinova V.V. Model’ dvizheniya vozdushnogo ob’’ekta v usloviyakh apriornoy neopredelennosti otnositel’no vremeni nachala i intensivnosti manevra [Aircraft object motion model in conditions of prior uncertainty to starting time and manoeuvre intensity]. Aktual’nye voprosy razvitiya vooruzheniya, voennoy i spetsial’noy tekhniki voysk protivovozdushnoy i protivoraketnoy oborony, kosmicheskikh voysk vozdushno-kosmicheskikh sil. Mat. nauch.-metod. tr. vseross. nauch.-prakt. konf. [Actual questions of developing weapon, military and special purpose equipment of air and missile defense troops, and space forces. Proc. Russ. Sci.-Pract. Conf.]. 2017, pp. 216–222.