It has generally been accepted that in a two-branch diversity receiver a near maximum diversity advantage is realized when the cross correlation between the two branches is less than 0.7. Based on this figure, space diversity reception at the mobile presents little problem since the antenna separation distances that achieve this mount of decorrelation in the mobile environment are very small (≤20 cm at 850 MHz). However, the space diversity antenna separation requirement at the land site necessary to achieve the same amount of signal decorrelation is in the range of 10 wavelengths or more at antenna elevations of 150 ft or greater. Therefore, a comprehensive characterization of the effect of changing the cross correlation between the two received signals at the land site is important to effective system design. The performance of the two-branch equal-gain diversity system as a function of the cross-correlation between the two received signals from the diversity antennas is described. The cumulative probability distribution, level crossing rates, and duration of fades from a two-branch equal-gain combined diversity signal with variable correlation between the two branches are described also.
[1]
Sang-Bin Rhee,et al.
Results of Suburban Base Station Spatial Diversity Measurements in the UHF Band
,
1974,
IEEE Trans. Commun..
[2]
S. O. Rice,et al.
Statistical properties of a sine wave plus random noise
,
1948,
Bell Syst. Tech. J..
[3]
W.C.-Y. Lee.
Effects on Correlation Between Two Mobile Radio Base-Station Antennas
,
1973,
IEEE Trans. Commun..
[4]
W.C.-Y. Lee.
A study of the antenna array configuration of an M-branch diversity combining mobile radio receiver
,
1971
.
[5]
S. Rice.
Mathematical analysis of random noise
,
1944
.
[6]
W. C. Y. Lee.
Antenna spacing requirement for a mobile Radio base-station diversity
,
1971
.