Communicating over nonstationary nonflat wireless channels

We develop the concept of joint time-frequency estimation of wireless channels. The motivation is to optimize channel usage by increasing the signal-to-noise ratio (SNR) after demodulation while keeping training overhead at a moderate level. This issue is important for single-input single-output (SI...

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Bibliographic Details
Published in:IEEE transactions on signal processing 2005-06, Vol.53 (6), p.2216-2227
Main Authors: Sigloch, K., Andrews, M.R., Mitra, P.P., Thomson, D.J.
Format: Article
Language:English
Subjects:
Acoustic pulses
Acoustics
Applied sciences
Bandwidth
Bit error rate
Channel estimation
Channels
Demodulation
Detection, estimation, filtering, equalization, prediction
discrete prolate spheroidal sequences
Earth Sciences
Engineering Sciences
Environmental Sciences
Exact sciences and technology
Fluctuation
Fluctuations
Frequency estimation
Geophysics
Information, signal and communications theory
Instrumentation and Detectors
Intersymbol interference
Mathematical models
MIMO
modulation
Noise levels
nonflat
nonstationary
Physics
Sciences of the Universe
Signal and communications theory
Signal and Image processing
Signal to noise ratio
Signal, noise
Slepian
Spectra
Symbols
Telecommunications and information theory
Temporal logic
Time frequency analysis
time-frequency
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Summary:We develop the concept of joint time-frequency estimation of wireless channels. The motivation is to optimize channel usage by increasing the signal-to-noise ratio (SNR) after demodulation while keeping training overhead at a moderate level. This issue is important for single-input single-output (SISO) and multiple-input multiple-output (MIMO) systems but particularly so for the latter. Linear operators offer a general mathematical framework for symbol modulation in channels that vary both temporally and spectrally within the duration and bandwidth of one symbol. In particular, we present a channel model that assumes first-order temporal and spectral fluctuations within one symbol or symbol block. Discrete prolate spheroidal sequences (Slepian sequences) are used as pulse-shaping functions. The channel operator in the Slepian basis is almost tridiagonal, and the simple intersymbol interference pattern can be exploited for efficient and fast decoding using Viterbi's algorithm. To prove the concept, we use the acoustic channel as a meaningful physical analogy to the radio channel. In acoustic 2 /spl times/ 2 MIMO experiments, our method produced estimation results that are superior to first-order time-only, frequency-only, and zeroth-order models by 7.0, 9.4, and 11.6 db. In computer simulations of cellular wireless channels with realistic temporal and spectral fluctuations, time-frequency estimation gains us 12 to 18 db over constant-only estimation in terms of received SNR when signal-to-receiver-noise is 10 to 20 db. The bit error rate (BER) decreases by a factor of two for a binary constellation.
ISSN:1053-587X
1941-0476
DOI:10.1109/TSP.2005.847849