Author :
Hochwald, Bertrand M. ; Marzetta, Thomas L. ; Hassibi, Babak
Author_Institution :
Math. Sci. Res. Center, Lucent Technol. Bell Labs., Murray Hill, NJ, USA
Abstract :
Prior treatments of space-time communications in Rayleigh flat fading generally assume that channel coding covers either one fading interval-in which case there is a nonzero “outage capacity”-or multiple fading intervals-in which case there is a nonzero Shannon capacity. However, we establish conditions under which channel codes span only one fading interval and yet are arbitrarily reliable. In short, space-time signals are their own channel codes. We call this phenomenon space-time autocoding, and the accompanying capacity the space-time autocapacity. Let an M-transmitter antenna, N-receiver antenna Rayleigh flat fading channel be characterized by an M×N matrix of independent propagation coefficients, distributed as zero-mean, unit-variance complex Gaussian random variables. This propagation matrix is unknown to the transmitter, it remains constant during a T-symbol coherence interval, and there is a fixed total transmit power. Let the coherence interval and number of transmitter antennas be related as T=βM for some constant β. A T×M matrix-valued signal, associated with R·T bits of information for some rate R is transmitted during the T-symbol coherence interval. Then there is a positive space-time autocapacity Ca such that for all R<Ca, the block probability of error goes to zero as the pair (T, M)→∞ such that T/M=β. The autocoding effect occurs whether or not the propagation matrix is known to the receiver, and Ca=Nlog(1+ρ) in either case, independently of β, where ρ is the expected signal-to-noise ratio (SNR) at each receiver antenna. Lower bounds on the cutoff rate derived from random unitary space-time signals suggest that the autocoding effect manifests itself for relatively small values of T and M. For example, within a single coherence interval of duration T=16, for M=7 transmitter antennas and N=4 receiver antennas, and an 18-dB expected SNR, a total of 80 bits (corresponding to rate R=5) can theoretically be transmitted with a block probability of error less than 10-9, all without any training or knowledge of the propagation matrix
Keywords :
Gaussian distribution; Rayleigh channels; channel capacity; channel coding; error statistics; matrix algebra; radio links; radiowave interferometry; receiving antennas; transmitting antennas; Gaussian distribution; Rayleigh flat fading; SNR; block error probability; channel codes; channel coding; cutoff rate; fading interval; independent propagation coefficients; lower bound; outage capacity; propagation matrix; receiver antennas; signal-to-noise ratio; space-time autocapacity; space-time autocoding; space-time communications; space-time signals; symbol coherence interval; total transmit power; transmitter antennas; unit-variance complex Gaussian random variables; zero-mean Gaussian random variables; Antenna theory; Antennas and propagation; Automatic programming; Channel coding; Fading; Random variables; Rayleigh channels; Receiving antennas; Transmitters; Transmitting antennas;
