Analysis of multiuser MIMO downlink networks using linear transmitter and receivers
EURASIP Journal on Wireless Communications and Networking - Special issue on multiuser MIMO networks
Downlink throughput enhancement of IEEE 802.11a/g using SDMA with a multi-antenna access point
Signal Processing - Special section: Advances in signal processing-assisted cross-layer designs
IEICE Transactions on Fundamentals of Electronics, Communications and Computer Sciences
IEEE Transactions on Wireless Communications
Channel ranking based joint symbols detection for MQRD-PCM/MIMO-OFDM
CCNC'09 Proceedings of the 6th IEEE Conference on Consumer Communications and Networking Conference
Multiple CFOs in OFDM-SDMA uplink: interference analysis and compensation
EURASIP Journal on Wireless Communications and Networking - Special issue on synchronization in wireless communications
An efficient MIMO detection algorithm employed in imperfect noise estimation
WSEAS TRANSACTIONS on COMMUNICATIONS
GIIS'09 Proceedings of the Second international conference on Global Information Infrastructure Symposium
Estimation of residual carrier and sampling frequency offsets in OFDM-SDMA uplink transmissions
IEEE Transactions on Wireless Communications
Performance evaluation of capacity-aware MIMO beamforming schemes in OFDM-SDMA systems
IEEE Transactions on Communications
Independent component analysis based semi-blind I/Q imbalance compensation for MIMO OFDM systems
IEEE Transactions on Wireless Communications
Antenna Array Designs for OFDM WLAN Indoor Transmission
Wireless Personal Communications: An International Journal
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Two major technical challenges in the design of future broadband wireless networks are the impairments of the propagation channel and the need for spectral efficiency. To mitigate the channel impairments, orthogonal frequency division multiplexing (OFDM) can be used, which transforms a frequency-selective channel in a set of frequency-flat channels. On the other hand, to achieve higher spectral efficiency, space division multiple access (SDMA) can be used, which reuses bandwidth by multiplexing signals based on their spatial signature. In this paper, we present a combined OFDM/SDMA approach that couples the capabilities of the two techniques to tackle both challenges at once. We propose four algorithms, ranging from a low-complexity linear minimum mean squared error (MMSE) solution to the optimal maximum likelihood (ML) detector. By applying per-carrier successive interference cancellation (pcSIC), initially proposed for DS-CDMA, and introducing selective state insertion (SI), we achieve a good tradeoff between performance and complexity. A case study demonstrates that, compared to the MMSE approach, our pcSIC-SI-OFDM/SDMA algorithm obtains a performance gain of 10 dB for a BER of 10-3, while it is only three times more complex. On the other hand, it is two orders of magnitude less complex than the ML approach, for a performance penalty of only 2 dB