Abstract
The objective of this chapter is to illustrate that an electromagnetic macro model can accurately predict the dominant component of the propagation path loss for a cellular wireless communication. The reason a macro model can provide accurate results that agree with experiments is because the trees, buildings, and other man-made obstacles contribute second-order effects to the propagation path loss as the dominant component that affects propagation is the free-space propagation of the signal and the effect of the earth over which the signal is propagating. It is demonstrated using both measurements and an analytical theoretical model that the propagation path loss inside a cellular communication cell is first 30 dB per decade of distance, and later on, usually outside the cell, it is 40 dB per decade of the electrical distance between the transmitter and the receiver irrespective of their heights from the ground. This implies that the electric field decays first at a rate of ρ ─1.5 inside the cell and later on, usually outside the cell, as ρ ─2, where ρ stands for the distance between the transmitter and the receiver. This appears to be independent of the frequency of operation in the band of interest and the parameters of the ground. It is also illustrated that the so-called slow fading is due to the interference between the direct wave and the ground wave as introduced by Sommerfeld over 100 years ago. All these statements can be derived from the approximate integration of the Sommerfeld integrals using a modified path for the steepest descent method and also using a purely numerical methodology. Finally, an optical analog is described based on the image theory developed by Van der Pol to illustrate the mechanism of radio wave propagation in a cellular wireless communication system.
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References
Abdallah MN, Dyab W, Sarkar TK, Prasad MVSN, Misra CS, Lampérez AG, Salazar-Palma M, Ting SW (2014) Further validation of an electromagnetic macro model for analysis of propagation path loss in cellular networks using measured driving-test data. IEEE Antennas Propagat Mag 56:108–129
Baños A (1966) Dipole radiation in the presence of a conducting half-space. Pergamon Press, Oxford
Booker HG, Clemmow PC (1950) A relation between the Sommerfeld theory of radio propagation over a flat earth and the theory of diffraction at a straight edge. Proc IEE 97:18–27
Burrows CR (1937) The surface wave in radio propagation over plane earth. Proc IRE 25:219–229
Collin RE (2004) Hertzian dipole radiating over a lossy earth or sea: some early and late 20th-century controversies. IEEE Antennas Propagat Mag 46:64–79
De A, Sarkar TK, Salazar-Palma M (2010) Characterization of the far field environment of antennas located over a ground plane and implications for cellular communication systems. IEEE Antennas Propagat Mag 52:19–40
Djordjevic AR, Bazdar MB, Sarkar TK, Harrington RF (2002) AWAS version 2.0: analysis of wire antennas and scatterers, software and user’s manual. Artech House, Norwood
Dyab WM, Sarkar TK, Salazar-Palma M (2013) A physics-based Green’s function for analysis of vertical electric dipole radiation over an imperfect ground plane. IEEE Trans Antennas Propagat 61:4148–4157
Fujimoto K (2008) Mobile antenna systems handbook, 3rd edn. Artech House, Norwood
Gabor D (1953) Communication theory and physics. IRE Trans Informat Theory 1:48–59
Goldsmith A (2005) Wireless communications. Cambridge University Press, Cambridge
IEEE Standard Definitions of Terms for Radio Wave Propagation (1998) http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=705931&userType=inst&tag=1. Accessed Mar 2015
Ishimaru A (1991) Electromagnetic wave propagation, radiation, and scattering. Englewood Cliffs, Prentice Hall. Chapter 15 and Appendix to Chapter 15
Ji Z, Li BH, Wang HX, Chen HY, Sarkar TK (2001) Efficient ray-tracing methods for propagation prediction for indoor wireless. IEEE Antennas Propagat Mag 43:41–49
Ji Z, Sarkar TK, Li BH (2002) Methods for optimizing the location of base stations for indoor wireless communications. IEEE Trans Antennas Propagat 50:1481–1483
Lazarus M (2010) The great spectrum famine. IEEE Spectr 47:26–31
McMillan RW (2006) Terahertz Imaging, Millimeter-Wave Radar. Advances in Sensing with Security Applications, Springer Netherlands, 2:243–268
Okumura T, Ohmori E, Kawano T, Fukuda K (1968) Field strength and its variability in VHF and UHF land mobile service. Rev Elect Commun Lab 16:825–873
Sarkar TK (1977) Analysis of arbitrarily oriented thin wire antennas over a plane imperfect ground. AEÜ 31:449–457
Sarkar TK, Ji Z, Kim K, Medouri A, Salazar Palma M (2003) A survey of various propagation models for wireless communication. IEEE Antennas Propagat Mag 45:51–82
Sarkar TK, Dyab W, Abdallah MN, Salazar-Palma M, Prasad MVSN, Barbin S, Ting SW (2012a) Physics of propagation in a cellular wireless communication environment. Radio SciBull 343:5–21. http://www.ursi.org/files/RSBissues/RSB_343_2012_12.pdf. Accessed 1 Mar 2015
Sarkar TK, Dyab W, Abdallah MN, Salazar-Palma M, Prasad MVSN, Ting SW, Barbin S (2012b) Electromagnetic macro modeling of propagation in mobile wireless communication: theory and experiment. IEEE Antennas Propagat Mag 54:17–43
Sarkar TK, Dyab WM, Abdallah MN, Salazar-Palma M, Prasad MVSN, Ting SW (2014) Application of the Schelkunoff formulation to the Sommerfeld problem of a vertical electric dipole radiating over an imperfect ground. IEEE Trans Antennas Propagat 62:4162–4170
Sommerfeld AN (1909) Propagation of waves in wireless telegraphy. Ann Phys 28:665–736
Sommerfeld AN (1926) Propagation of waves in wireless telegraphy. Ann Phys 81:1135–1153
Stratton JA (1941) Electromagnetic theory. McGraw-Hill Book, New York
Van der Pol B (1935) Theory of the reflection of light from a point source by a finitely conducting flat mirror with application to radiotelegraphy. Physics 2:843–853
Weyl H (1919) Propagation of electromagnetic waves over a plane conductor. Ann Phys 60:481–500
www.prometheus-us.com/asi/sensors2005/papers/mcmillan.pdf. Accessed 21 Mar 2015
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Salazar-Palma, M., Sarkar, T.K., Abdallah, M.N., Dyab, W., Prasad, M.V.S.N., Ting, S.W. (2016). Physics and Mathematics of Radio Wave Propagation in Cellular Wireless Communications. In: Chen, Z., Liu, D., Nakano, H., Qing, X., Zwick, T. (eds) Handbook of Antenna Technologies. Springer, Singapore. https://doi.org/10.1007/978-981-4560-44-3_120
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DOI: https://doi.org/10.1007/978-981-4560-44-3_120
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