Title :
Full-diversity full-rate complex-field space-time coding
Author :
Ma, Xiaoli ; Giannakis, Georgios B.
Author_Institution :
Dept. of Electr. & Comput. Eng., Auburn Univ., AL, USA
fDate :
11/1/2003 12:00:00 AM
Abstract :
Exciting developments in wireless multiantenna communications have led to designs aiming mainly at one of two objectives: either high-performance by enabling the diversity provided by multi-input multi-output (MIMO) channels or high-rates by capitalizing on space-time multiplexing gains to realize the high capacity of MIMO fading channels. By concatenating a linear complex-field coder (a.k.a. linear precoder) with a layered space-time mapper, we design systems capable of achieving both goals: full-diversity and full-rate (FDFR), with any number of transmit- and receive-antennas. We develop FDFR designs not only for flat-fading but for frequency-selective, or, time-selective fading MIMO channels as well. Furthermore, we establish the flexibility of our FDFR designs in striking desirable performance-rate-complexity tradeoffs. Our theoretical claims are confirmed by simulations.
Keywords :
MIMO systems; antenna arrays; channel capacity; concatenated codes; diversity reception; linear codes; receiving antennas; reviews; space-time codes; transmitting antennas; channel capacity; concatenated code; frequency-selective channels; full-diversity complex-field space-time coding; full-rate complex-field space-time coding; high-performance; layered space-time mapper; linear complex-field coder; linear precoder; multi-input multi-output channels; performance-rate-complexity tradeoffs; receive-antennas; simulations; space-time multiplexing gain; time-selective fading MIMO channels; transmit-antennas; wireless multiantenna communications; Bandwidth; Decoding; Delay; Fading; Frequency diversity; Helium; MIMO; OFDM; Receiving antennas; Wireless communication;
Journal_Title :
Signal Processing, IEEE Transactions on
DOI :
10.1109/TSP.2003.818206
