Title :
Iterative maximum-likelihood sequence estimation for space-time coded systems
Author :
Li, Yingxue ; Georghiades, Costas N. ; Huang, Garng
Author_Institution :
Dept. of Electr. Eng., Texas A&M Univ., College Station, TX, USA
fDate :
6/1/2001 12:00:00 AM
Abstract :
In previous work on decoding space-time codes, it is either assumed that perfect channel state information (CSI) is present, or a channel estimate is obtained using pilot symbols and then used as if it were perfect to extract symbol estimates. In the latter case, a loss in performance is incurred, since the resulting overall receiver is not optimal. We look at maximum-likelihood (ML) sequence estimation for space-time coded systems without assuming CSI. The log-likelihood function is presented for both-quasi-static and nonstatic fading channels, and an expectation-maximization (EM)-based algorithm is introduced for producing ML data estimates, whose complexity is much smaller than a direct evaluation of the log-likelihood function. Simulation results indicate the EM-based algorithm achieves a performance close to that of a receiver which knows the channel perfectly
Keywords :
decoding; diversity reception; fading channels; land mobile radio; maximum likelihood sequence estimation; optimisation; quadrature phase shift keying; radio receivers; ML data estimates; QPSK; channel estimate; complexity; decoding; expectation-maximization based algorithm; iterative maximum-likelihood sequence estimation; log-likelihood function; mobile radio system; nonstatic fading; nonstatic fading channels; perfect channel state information; pilot symbols; quasi-static fading channels; receiver; simulation results; space-time coded systems; symbol estimates; transmitter diversity; trellis-based eight-state quadrature PSK; trellis-based four-state quadrature PSK; Channel state information; Covariance matrix; Fading; Iterative decoding; Maximum likelihood decoding; Maximum likelihood estimation; Receiving antennas; Signal processing algorithms; State estimation; Transmitting antennas;
Journal_Title :
Communications, IEEE Transactions on
