P1: JDW
Shankar WL040/Bidgolio-Vol I WL040-Sample.cls June 19, 2003 16:49 Char Count= 0
126 PROPAGATIONCHARACTERISTICS OFWIRELESSCHANNELSBuilding
Transmitter Receiver
Building
Transmitter
Receiver
Transmitter
Receiver
Figure 2: Various propagation mechanisms are shown: reflection (left), diffraction (center), and scattering (right).Modeling of Power Loss
Several models are available to predict the median
value of the received power (Har, Xia, & Bertoni, 1999;
Hata, 1980; Lee, 1986; Oda, Tsunkewa, & Hata, 2000;
Okumura, Ohmori, & Fukuda, 1968; Vogel & Hong, 1988).
These are available for propagation outdoors and in-
doors (Bultitude, Mahmoud, & Sullivan, 1989; Durgin,
Rappaport, & Xu, 1998; Harley, 1989; Lott & Forkel, 2001;
Rappaport & Sandhu, 1994). They are also available for
various frequency bands that are of interest in wireless
communications. Instead of concentrating on these mod-
els, I initially describe one of the simple ways of predictingloss based on the concept of thepath loss exponent.Toun-
derstand this concept, consider the case of a line-of-sight
propagation in free space as shown in Figure 1. IfPtis the
transmitted power inW(Watts), the received powerPd
(W) at a distancedfrom the transmitter is given by Friis
formula (IEEE, 1988),Pd=PtGtGr(
λ
4 πd) 2
W, (1)whereGt=gain of the transmitting antenna,Gr=gain of
the receiving antenna, andλ=free space wavelength=fc 0 ,Distance kmReceived Power dBma. DistancekmReceived Power dBmDistance mReceived Power dBmb. Distance mReceived Power dBmc. WavelengthsReceived Power dBmFigure 3: The plot of the received signal: (a) attenuation; (b) long-term fading; (c) short-term fading.