Assessing the effect of DS-CDMA chip rate on RAKE branch statistics using a ray-tracing propagation model

Author

Anderson, H.R. ; McGeehan, J.P.

Author_Institution

Centre for Commun. Res., Bristol Univ., UK

Volume

1

fYear

1994

fDate

18-23 Sep 1994

Firstpage

33

Abstract

An important improvement in the performance of CDMA and other wideband digital communication systems can be achieved using a RAKE receiver architecture and diversity combining of its branches. The paper presents an analysis of RAKE branch statistics as a function of chipping or channel symbol transmission rate for urban microcells. A deterministic ray-tracing model is used to provide realistic, site-specific estimates of the time dispersion in the dynamic fading channel. The results of the analysis show that increased chipping rates produce increasingly Ricean fading distributions on the diversity branches along with increased power in the higher order diversity branches. Increased diversity branch power results in more effective diversity combining and improved signal-to-noise ratios of the combined branch signals

Keywords

digital radio; DS-CDMA chip rate; RAKE branch statistics; Ricean fading distributions; channel symbol transmission rate; diversity branch power; diversity combining; dynamic fading channel; performance; ray-tracing propagation model; signal-to-noise ratios; site-specific estimates; time dispersion; urban microcells; wideband digital communication systems; Digital communication; Diversity reception; Fading; Microcell networks; Multiaccess communication; Multipath channels; Statistical analysis; Statistical distributions; Statistics; Wideband;

fLanguage

English

Publisher

ieee

Conference_Titel

Personal, Indoor and Mobile Radio Communications, 1994. Wireless Networks - Catching the Mobile Future., 5th IEEE International Symposium on

Conference_Location

The Hague

Print_ISBN

90-5199-193-2

Type

conf

DOI

10.1109/WNCMF.1994.530762

Filename

530762