Title :
A stochastic model of the temporal and azimuthal dispersion seen at the base station in outdoor propagation environments
Author :
Pedersen, Klaus Ingemann ; Mogensen, Preben E. ; Fleury, Bernard H.
Author_Institution :
Center for PersonKommunikation, Aalborg Univ., Denmark
fDate :
3/1/2000 12:00:00 AM
Abstract :
A simple statistical model of azimuthal and temporal dispersion in mobile radio channels is proposed. The model includes the probability density function (PDF) of the delay and azimuth of the impinging waves as well as their expected power conditioned on the delay and azimuth. The statistical properties are extracted from macrocellular measurements conducted in a variety of urban environments. It is found that in typical urban environments the power azimuth spectrum (PAS) is accurately described by a Laplacian function, while a Gaussian PDF matches the azimuth PDF. Moreover, the power delay spectrum (PDS) and the delay PDF are accurately modeled by an exponential decaying function. In bad urban environments, channel dispersion is better characterized by a multicluster model, where the PAS and PDS are modeled as a sum of Laplacian functions and exponential decaying functions, respectively
Keywords :
Gaussian distribution; UHF radio propagation; cellular radio; dispersive channels; exponential distribution; multipath channels; stochastic processes; Gaussian PDF; Laplacian function; azimuthal dispersion; base station; channel dispersion; delay; delay PDF; exponential decaying function; macrocellular measurements; mobile radio channels; multicluster model; outdoor propagation environments; power azimuth spectrum; power delay spectrum; probability density function; statistical model; stochastic model; temporal dispersion; urban environments; Antenna arrays; Antenna measurements; Antennas and propagation; Azimuth; Base stations; Diversity reception; Laplace equations; Probability density function; Propagation delay; Stochastic processes;
Journal_Title :
Vehicular Technology, IEEE Transactions on
