Abstract :
The performance of a cellular mobile radio system with frequency reuse is evaluated in terms of outage probability. Deterministic path loss, log-normal shadowing, and Ricean fading are accounted for, and the use of diversity and power control is considered in order to enhance system performance. Both hexagonal and lineal cells are considered. Particular attention is given to the sensitivity of the outage probability to the system parameters, especially those related to the propagation model (fading, shadowing, and path loss). It is seen that diversity and power control can improve the system behavior. The performance is sensitive to the fading parameter (i.e., the Rice factor) of the intended user, but is relatively independent of that of the interferers. Also, a significant dependence is observed on the shadowing parameter, whereas a limited dependence is seen on the outage threshold and the channel utilization. Finally, the presence of a dual path loss law degrades the performance, and the outage probability increases as the breakpoint distance gets larger
Keywords :
Rician channels; cellular radio; diversity reception; fading; land mobile radio; log normal distribution; losses; multipath channels; power control; radiofrequency interference; telecommunication control; Rice factor; Ricean fading; breakpoint distance; channel utilization; deterministic path loss; diversity; dual path loss law; fading parameter; frequency reuse; hexagonal cells; interferers; lineal cells; log-normal shadowing; mobile radio cellular systems; outage probability; outage threshold; performance; power control; propagation model; system parameters; system performance; Degradation; Fading; Frequency; Land mobile radio; Performance loss; Power control; Power system modeling; Propagation losses; Shadow mapping; System performance;
