Title :
Turbo-BLAST: performance evaluation in correlated Rayleigh-fading environment
Author :
Sellathurai, Mathini ; Haykin, Simon
Author_Institution :
McMaster Univ., Hamilton, Ont., Canada
fDate :
4/1/2003 12:00:00 AM
Abstract :
Theoretical investigations of spatially correlated multitransmit and multireceive (MTMR) links show that not only independently and identically distributed links, but also spatially correlated links can offer linear capacity growth with increasing number of transmit and receive antennas. We explore the suitability of the turbo-BLAST architecture in correlated Rayleigh-fading MTMR environments. In particular, for an MTMR system with a large number of receive antennas, a near optimal performance can be achieved by the turbo-BLAST architecture in spatially and temporarily correlated Rayleigh-fading environments. The performance of turbo-BLAST, in terms of both bit-error rate and spectral efficiency, is analyzed empirically in indoors and correlated outdoor environments.
Keywords :
Rayleigh channels; antenna arrays; channel capacity; correlation methods; decoding; error statistics; indoor radio; land mobile radio; radio links; receiving antennas; space-time codes; transmitting antennas; turbo codes; BER; Bell Labs Layered Spacetime; MTMR system; bit-error rate; correlated Rayleigh-fading; correlated outdoor environments; i.i.d. links; independently identically distributed links; indoors environments; linear capacity growth; mobile channels; multireceive links; multitransmit links; optimal performance; performance evaluation; random interleavers; random layered space-time codes; receive antennas; spatially correlated links; spectral efficiency; transmit antennas; turbo-BLAST architecture; Bit error rate; Channel capacity; Codecs; Interference; Linear antenna arrays; Maximum likelihood decoding; Performance analysis; Rayleigh channels; Receiving antennas; Space technology;
Journal_Title :
Selected Areas in Communications, IEEE Journal on
DOI :
10.1109/JSAC.2003.809628
