|

Generalized Ambiguity Function for Trajectory Parameters for Forward-Scattering Bistatic MIMO Radar

Authors: Vodolazov A.V., Chapurskii V.V. Published: 29.09.2017
Published in issue: #5(116)/2017  
DOI: 10.18698/0236-3933-2017-5-85-98

  
Category: Instrument Engineering, Metrology, Information-Measuring Instruments and Systems | Chapter: Radio Equipment, Television Systems and Devices  
Keywords: forward-scattering radar, generalized correlation integral, generalized ambiguity function, wideband signal, MIMO radar

In the article, an analytic expression of the generalized ambiguity function for the forward-scattering bistatic radar is derived according to multi-frequency MIMO location. Two-dimensional cross sections of the generalized ambiguity function are presented for narrowband and wideband forward-scattering bistatic radar and for multi-frequency forward-scattering MIMO radar. Based on these results, we carried out a comparative analysis of these systems and showed major advantages of using wideband signal and principles of MIMO for forward-scattering bistatic radar

References

[1] Scolnik M.I. Radar handbook. New York, McGraw-Hill, 1990. 1351 p.

[2] Willis N.J. Bistatic radar. Sci. Tech Publishing Inc., 1995. 337 p.

[3] Ufimtsev P.Ya. Black bodies and shadow emission. Radiotekhnika i elektronika, 1989, vol. 34, no. 2, pp. 2519–2527 (in Russ.).

[4] Chapurskiy V.V. Calculation of inverted hologram spectrum and effective reflection surface of complex objects in case of forward scattering. Izvestiya vysshikh uchebnykh zavedeniy. Radioelektronika [Radioelectronics and Communications Systems], 1989, vol. 32, no. 7, pp. 75–77 (in Russ.).

[5] Blyakhman A.B., Runova I.A. Bistatic effective reflection surface and object detection using forward-scattering radiolocation. Radiotekhnika i elektronika, 2001, vol. 6, no. 4, pp. 424–432 (in Russ.).

[6] Blyakhman A.B. Multistatic forward scattering radar. PIERS Workshop on Advances in Radar methods, Italy, Baveno, July 1998, pp. 107–113.

[7] Chapurskiy V.V. WB and UWB signal notation and their generalized uncertainty function in forward-scattering radiolocation. Vserossiyskaya nauchnaya konferentsiya «Sverkhshirokopolosnye signaly v radiolokatsii, svyazi i akustike» [Russ. Sci. Conf. "Ultra-wideband signals in radiolocation, communication and acoustics"]. 2003, pp. 429–434 (in Russ.).

[8] Fishler E., Haimovich A., Blum R., Chizhik D., Cimini L., Valenzuela R. MIMO radar: An idea whose time has come. Proc. of the IEEE Radar Conference, 2004, pp. 71–78. DOI: 10.1109/NRC.2004.1316398

[9] Myakinkov A.V., Smirnova D.M. Ground targets detection in forward-scattering radar radiolocation system. Izvestiya vysshikh uchebnykh zavedeniy Rossii. Radioelektronika [Journal of the Russian Universities. Radioelectronics], 2010, no. 5, pp. 47–55 (in Russ.).

[10] Myakinkov A.V., Smirnova D.M. Measurement of coordinates of the targets placed behind of radio-transparent barrier with multistatic ultrawide band radar. Ultrawideband and Ultrashort Impulse Signals, Sevastopol, 2010, pp. 147–149.

[11] Verba V.S., Neronskiy L.B., Osipov I.G., Turuk V.E. Radiolokatsionnye sistemy zemleobzora kosmicheskogo bazirovaniya [Spaceborne radiolocation systems of Earth survey]. Moscow, Radiotekhnika Publ., 2012. 680 p.

[12] Cherniakov M., ed. Bistatic radar: Emerging technology. Wiley, 2008. 406 p.

[13] Chapurskiy V.V. Izbrannye zadachi teorii sverkhshirokopolosnykh radiolokatsionnykh sistem [Selected problems of ultra-wideband radiolocation systems]. Moscow, Bauman MSTU Publ., 2012. 279 p.