Title :
Iterative detection and decoding in 3GPP LTE-based massive MIMO systems
Author :
Wu, Min ; Dick, Chris ; Cavallaro, J.R. ; Studer, Christoph
Author_Institution :
Dept. of ECE, Rice Univ., Houston, TX, USA
Abstract :
Massive multiple-input multiple-output (MIMO) is expected to be a key technology in next-generation multi-user cellular systems for achieving higher throughput and better link reliability than existing (small-scale) MIMO systems. In this work, we develop a novel, low-complexity iterative detection and decoding algorithm for single carrier frequency division multiple access (SC-FDMA)-based massive MIMO systems, such as future 3GPP LTE-based systems. The proposed algorithm combines a novel frequency-domain minimum mean-square error (FD-MMSE) equalization method with parallel interference cancellation (PIC), requires low computational complexity, and achieves near-optimal error-rate performance in 3GPP-LTE-based massive MIMO systems having only 2× more base-station antennas than users.
Keywords :
3G mobile communication; Long Term Evolution; MIMO communication; cellular radio; computational complexity; equalisers; frequency-domain analysis; interference suppression; iterative decoding; least mean squares methods; mobile antennas; radiofrequency interference; 3GPP LTE-based massive MIMO systems; FD-MMSE; SC-FDMA; base-station antennas; frequency-domain minimum mean-square error equalization method; link reliability; low computational complexity; low-complexity iterative detection-and-decoding algorithm; massive multiple-input multiple-output system; near-optimal error-rate performance; next-generation multi-user cellular systems; parallel interference cancellation; single carrier frequency division multiple access-based massive MIMO systems; throughput; Antennas; Complexity theory; Decoding; Detectors; Frequency-domain analysis; Iterative decoding; MIMO;
Conference_Titel :
Signal Processing Conference (EUSIPCO), 2014 Proceedings of the 22nd European
Conference_Location :
Lisbon
