Attenuation measurements were implemented at L-band (1.5 GHz) in southeastern Australia during an 11-day period in October 1988 as part of a continuing examination of the propagation effects due to roadside trees and terrain for mobile-satellite service. Beacon transmissions from the geostationary ETS-V and IPORS satellites were observed. The Australian campaign expanded to another continent our Mobile Satellite Service data base of measurements executed in the eastern and southwestern United States regions. An empirical fade distribution model based on U.S. data predicted the Australian results with errors generally less than 1 dB in the 1-20 percent probability region. Directive antennas are shown to suffer deeper fades under severe shadowing conditions (3 dB excess at 4 percent), the equal-probability isolation between co- and cross-polarized transmissions deteriorated to 10 dB at the 5 dB fade level, and antenna diversity reception may reduce unavailability of the system by a factor of 2-8.
[1]
W. J. Vogel,et al.
Measurement and modeling of land mobile satellite propagation at UHF and L-band
,
1988
.
[2]
W. J. Vogel,et al.
Tree attenuation at 869 MHz derived from remotely piloted aircraft measurements
,
1986
.
[3]
Yoshihiro Hase,et al.
Fade-durations derived from land-mobile-satellite measurements in Australia
,
1991,
IEEE Trans. Commun..
[4]
W. J. Vogel,et al.
Mobile satellite system fade statistics for shadowing and multipath from roadside trees at UHF and L-band
,
1989
.
[5]
J. Goldhirsh,et al.
Roadside tree attenuation measurements at UHF for land mobile satellite systems
,
1987
.
[6]
W. Vogel,et al.
Mobile satellite system propagation measurements at L-band using MARECS-B2
,
1990
.
[7]
W. J. Vogel,et al.
Fade measurements at L-band and UHF in mountainous terrain for land mobile satellite systems
,
1988
.