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Abstrakty
A Yagi plasma antenna model was established by HFSS according to the relationship between plasma dielectric constant and electron density. The patterns were simulated by changing plasma parameters and the number of director dipoles. Results show that when the passive vibrators were switched off, the antenna is omnidirectional antenna. The directionality increases with the increase of the number of passive dipole and the main lobe of which narrows down. Then the plasma Yagi antenna model is established by plasma tube, the gain changed by changing the number of passive dipoles, so the plasma Yagi antenna has a very good reconfigurability. Results prove that the feasibility of the plasma Yagi antenna can be used on AIS base station of Ships’ Routeing waters. It can promote the communication and capability of maritime supervision in Ships’ Routeing waters.
Rocznik
Tom
Strony
179--184
Opis fizyczny
Bibliogr. 14 poz., rys., tab.
Twórcy
autor
- Shanghai Maritime University, Shanghai, China
autor
- Shanghai Maritime University, Shanghai, China
autor
- Shanghai Maritime University, Shanghai, China
autor
- Shanghai Maritime University, Shanghai, China
autor
- Shanghai Maritime University, Shanghai, China
autor
- Shanghai Maritime University, Shanghai, China
Bibliografia
- [1] Huang C H, Xiao Y J, Gao D Y et al. Evaluation model of navigation risk in routeing waters and its application [J]. China Safety Science Journal,2014,24(2): 93-99.
- [2] Liu Y H, Xiao Y J, Guan K P. Ships’ Routeing for NingboZhoushan core harbor area based on marine traffic investigation of AIS [J]. Journal of Shanghai Maritime University,2014,35(1): 1-5.
- [3] Zhao H C, Liu S B, Kong X K et al. Simulation and experimental study on the plasma Yagi antenna [J]. Journal of Microwaves,2014,30(1): 20-23.
- [4] Rayner J P, Whichello A P, Cheetham A D. Physical Characteristics of Plasma Antennas. IEEE Transactions on Plasma Science, 2004, 32(1): 269-281.
- [5] Huang F Y, Shi J M, Yuan Z C, et al. Theoretical and experimental study of plasma directional antenna array [J]. Acta. Phys. Sin.,2013,62 (15): 155201-1-155201-7.
- [6] Belyaev B. A., Leksikov A. A., Leksikov A. A. et al. Nonlinear Vehavior of Plasma Antenna Vibrator [J]. IEEE Trans. Plasma Sci., 2014, 42 (6): 1552-1559.
- [7] Liang Z W,Zhao G W, Xu J, et al. Analysis of Plasmacolumn antenna using moment method [J]. Chinese Journal of Radio Science,2008,23(4): 749-753.
- [8] Yuan Z C, Shi J M, Yu G F, Principles and realization of surface wave driven plasma antenna [J]. Electronic information countermeasure technology, 2006, 21(4): 3841.
- [9] Song Z, Zhang J H, Huang Y. Antenna and Propagation (The second edition). Xidian University Press:2011
- [10] Kraus J D Antenna (The third edition), Electronic industry press: 2006.
- [11] Zhang Z T, Zhao J S, Xu X W et al. Experimental Study on the Interaction of Electromagnetic Waves and Glow Plasma. Plasma Science and Technology, 2011, 13 (3): 279-285.
- [12] Zhao J S, Zhang Z T, Wang J, et al. A U-shape plasma antenna based on excitation of 5-20 kHz alternating current power supply [J]. Acta. Phys. Sin., 2012,61 (19): 301-307.
- [13] Zhao J S, Sun Y, Ni Y W, et al. Light-electricity method for measuring switch-on time of plasma antennas [J]. High Power Laser and Particle Beams, 2017, 29 (5): 1-7.
- [14] Zhao J S, Chen Y L, Sun Y, Wu H F, Liu Y, et al. Plasma antennas driven by 5-20kHz AC power supply [J]. AIP Advances 5, 2015, 127114.
Uwagi
Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2020).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-9c1d2392-8676-441a-a439-0363ea4888d5