An energy-efficient 64-QAM MIMO detector for emerging wireless standards

A power/area aware design is mandatory for the MIMO (Multi-Input Multi-Output) detectors used in LTE and WiMAX standards. The 64-QAM modulation used in the MIMO detector requires more detection effort compared to the smaller constellation sizes widely implemented in the literature. In this work we propose a new architecture for the K-best detector, which unlike the popular multi-stage architecture used for K-best detectors, implements just one core. Also, we introduce a slight modification to the K-best algorithm that reduces the number of multiplications by 44%, and reduces the total power consumption by 27%, without any noticeable performance degradation. The overall architecture consumes only 24KGate, which is the smallest area compared to the other implementations in the literature. It also results in an at least 4-fold greater throughput-efficiency (Mbps/KiloGate) compared to the other detectors, while consuming a small power. The decoder implemented in a commercial 130nm process provides a data-rate of 107Mbps, and consumes 54.4mW.

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