Title :
Diversity transmission and adaptive MLSE for digital cellular radio
Author :
Bontu, Chandra S. ; Falconer, David D. ; Strawczynski, Leo
Author_Institution :
Nortel, Ottawa, Ont., Canada
fDate :
9/1/1999 12:00:00 AM
Abstract :
Adaptive equalization at the mobile in conjunction with diversity transmission at the base station can combat the adverse effects of both frequency-selective and frequency-nonselective fading at the mobile receiver. This is suggested as an alternative to diversity combining at the mobile. Thus, a substantial saving in the mobile receiver´s implementation cost and power consumption is expected. In this paper, a time-domain multiple access system with two transmitting antennas at the base station and maximum-likelihood sequence estimation at the mobile is considered. Per-survivor processing (PSP), a combined channel-tracking and sequence-estimation algorithm, has been used for improving the system performance. System performance results in the presence of severe Doppler frequency shifts and additive white Gaussian noise in a flat fading channel are presented. The computational complexity and acquisition capabilities of the PSP algorithm are also presented
Keywords :
AWGN channels; adaptive equalisers; adaptive estimation; antenna arrays; cellular radio; computational complexity; digital radio; diversity reception; fading channels; maximum likelihood sequence estimation; time division multiple access; tracking; transmitting antennas; Doppler frequency shifts; PSP algorithm; acquisition capabilities; adaptive MLSE; adaptive equalization; additive white Gaussian noise; base station; channel-tracking; computational complexity; digital cellular radio; diversity combining; diversity transmission; flat fading channel; frequency-nonselective fading; frequency-selective fading; implementation cost; maximum-likelihood sequence estimation; mobile receiver; per-survivor processing; power consumption; sequence-estimation; system performance; time-domain multiple access system; transmitting antennas; Adaptive equalizers; Base stations; Costs; Diversity reception; Fading; Frequency diversity; Land mobile radio cellular systems; Maximum likelihood estimation; Receivers; System performance;
Journal_Title :
Vehicular Technology, IEEE Transactions on
