Lithuanian Journal of Physics article / Lietuvos fizikos žurnalo straipsnis

THEORETICAL ANALYSIS AND EXPERIMENTAL MEASUREMENT OF DIGITAL MULTI-BEAM PHASED ANTENNA ARRAY IN THE C FREQUENCY RANGE
Lu Guoming, Petr N. Zakharov, and Anatoliy F. Korolev
Faculty of Physics, Lomonosov Moscow State University, 119991, GSP-1, 1-2 Leninskiye Gory, Moscow, Russian Federation
E-mail: luguoming.hit@gmail.com
Received 5 September 2018; revised 6 November 2018; accepted 2 January 2019

The choice of elements for constructing a phased antenna array providing a relative frequency bandwidth up to 9% for the transmission or reception of wireless communication system information was made. Superposition of the excitation signals of a flat phased antenna array for a simultaneous emission of several independent beams in a radiation far field was used. Calculation and optimization of the progressive distribution of phase shifts in the excitation signal group in the horizontal and vertical directions of the phased array plane for the radiation (reception) of independent beams in spherical coordinates (azimuth and elevation) in space was performed. An experimental sample of the phased antenna array was developed using microstrip technology, which forms several beams in the radiation far field. An experimental measurement of the voltage standing wave ratio and relative frequency bandwidth of the sample developed by phased array microstrip and printing technology was carried out. The multi-beam phased antenna array will increase the number of subscribers for multi-user systems, as well as increase the energy efficiency for point-to-point communication by transmitting over multiple spatial trajectories.

Keywords: phased antenna array, radiation pattern, voltage standing wave ratio

SKAITMENINIŲ DAUGIAPLUOŠČIŲ FAZUOTŲ ANTENŲ RINKINIO TEORINĖ ANALIZĖ IR EKSPERIMENTINIS MATAVIMAS C DAŽNIŲ RUOŽE
Lu Guoming, Petr N. Zakharov, Anatoliy F. Korolev

Maskvos valstybinio Lomonosovo universiteto Fizikos fakultetas, Maskva, Rusijos Federacija

References / Nuorodos

[1] M.A. Jensen and J.W. Wallace, A review of antennas and propagation for MIMO wireless communications, IEEE Trans. Antennas Propag. 52, 2810– 2812 (2004),
https://doi.org/10.1109/TAP.2004.835272
[2] J.B. Andersen, Array gain and capacity for known random channels with multiple element arrays at both ends, IEEE J. Select Areas Commun. 18, 2172–2178 (2000),
https://doi.org/10.1109/49.895022
[3] J.W. Wallace, M.A. Jensen, A.L. Swindlehurst, and B.D. Jeffs, Experimental characterization of the MIMO wireless channel: Data acquisition and analysis, IEEE Trans. Wireless Commun. 2, 335–343 (2003),
https://doi.org/10.1109/TWC.2003.808975
[4] A.F. Molisch and M.Z. Win, MIMO systems with antenna selection, IEEE Microw. Mag. 5(1), 47–48 (2004),
https://doi.org/10.1109/MMW.2004.1284943
[5] L. Zheng and D. Tse, Diversity and multiplexing: A fundamental tradeoff in multiple antenna channels, IEEE Trans. Inf. Theory 49, 1073–1096 (2003),
https://doi.org/10.1109/TIT.2003.810646
[6] M. Lienard, P. Degauque, J. Baudet, and D. De gardin, Investigation on MIMO channels in subway tunnels, IEEE J. Select Areas Commun. 21, 332–339 (2003),
https://doi.org/10.1109/JSAC.2003.809627
[7] J. Zhang, Z. Zheng, Y. Zhang, J. Xi, X. Zhao, and G. Gui, 3D MIMO for 5G NR: Several observations from 32 to massive 256 antennas based on channel measurement, IEEE Commun. Mag. 6(3), 62–70 (2018),
https://doi.org/10.1109/MCOM.2018.1700846
[8] M.M. Lodro, N. Majeed, A.A. Khuwaja, A.H. Sodhro, and S. Greedy, in: Proceedings of the 2018 International Conference on Computing, Mathematics and Engineering Technologies (iCoMET) (2018) pp. 1–5
[9] S.F. Jilani and A. Alomainy, Millimetre-wave T-shaped MIMO antenna with defected ground structures for 5G cellular networks, IET Microw. Antenna P. 12(5), 672–677 (2018).
https://doi.org/10.1049/iet-map.2017.0467
[10] B.M. Petrov, Electrodynamics and Propagation of Radio Waves (Hotline-Telecom, Moscow, 2007) [in Russian].
[11] L. Guoming, P.N. Zakharov, and A.P. Sukhorukov, Simulation of low-sidelobe phased antenna array with circular polarization, Moscow Univer. Phys. Bull. 68(6), 437–442 (2013).
https://doi.org/10.3103/S0027134913060052
[12] V.I. Slyusar, Digital antenna arrays are the future of radiolocation, Electronics: NTB 3, 42–47 (2001) [in Russian]
[13] V.I. Slyusar, Phased antenna array of Thuraya system, Netw. Telecommun. 5, 54–58 (2002) [in Russian]
[14] K.A. Geniatulin and V.I. Nosov, Planning of satellite communication systems with zonal service, Vestnik SibSUTIS 4, 11–22 (2009) [in Russian]
[15] P.N. Zakharov, R.A. Dudov, E.V. Mikhailov, A.F. Korolev, and A.P. Sukhorukov, in: Proceedings of the 2009 Loughborough Antennas & Propagation Conference (LAPC) (Loughborough, UK, 2009) pp. 369–372
[16] O.G. Vendik and M.D. Parnes, Antennae with Electric Scanning (Radio and Communication, Moscow, 2001) [in Russian]
[17] A.A. Skvortsov, D.E. Pshonkin, M.N. Luk'yanov, and M.R. Rybakova, Deformations of aluminum alloys under the influence of an additional load, Periódico Tchê Química 15(30), 421–427 (2018)
[18] A.J. Fenn, D.H. Temme, W.P. Delaney, and W.E. Courtney, The development of phased-array radar technology, Lincoln Lab. J. 12, 320–340 (2000)
[19] A.S. Daryoush, Digitally beamformed multibeam phased array antennas for future communication satellites, in: Proceedings of the 2008 IEEE Radio and Wireless Symposium (2008) pp. 831–834