Power Scaling and Antenna Selection Techniques for Hybrid Beamforming in mmWave Massive MIMO Systems

With the advent of massive MIMO and mmWave, Antenna selection is the new frontier in hybrid beamforming employed in 5G base stations. Tele-operators are reworking on the components while upgrading to 5G where the antenna is a last-mile device. The burden on the physical layer not only demands smart and adaptive antennas but also an intelligent antenna selection mechanism to reduce power consumption and improve system capacity while degrading the hardware cost and complexity. This work focuses on reducing the power consumption and finding the optimal number of RF chains for a given millimeter wave massive MIMO system. At first, we investigate the power scaling method for both perfect Channel State Information (CSI) and imperfect CSI where the power is reduced by 1/number of antennas and 1/square root (number of antennas) respectively. We further propose to reduce the power consumption by emphasizing on the subdued resolution of Analog-to-Digital Converters (ADCs) with quantization awareness. The proposed algorithm selects the optimal number of antenna elements based on the resolution of ADCs without compromising on the quality of reception. The performance of the proposed algorithm shows significant improvement when compared with conventional and random antenna selection methods.

[1]  Wei Xu,et al.  Securing Massive MIMO Via Power Scaling , 2016, IEEE Communications Letters.

[2]  Rose Qingyang Hu,et al.  Key elements to enable millimeter wave communications for 5G wireless systems , 2014, IEEE Wireless Communications.

[3]  Erik G. Larsson,et al.  Massive MIMO in Real Propagation Environments: Do All Antennas Contribute Equally? , 2015, IEEE Transactions on Communications.

[4]  Robert W. Heath,et al.  Five disruptive technology directions for 5G , 2013, IEEE Communications Magazine.

[5]  Mérouane Debbah,et al.  Massive MIMO in the UL/DL of Cellular Networks: How Many Antennas Do We Need? , 2013, IEEE Journal on Selected Areas in Communications.

[6]  Robert W. Heath,et al.  Hybrid MIMO Architectures for Millimeter Wave Communications: Phase Shifters or Switches? , 2015, IEEE Access.

[7]  Larry J. Greenstein,et al.  An empirically based path loss model for wireless channels in suburban environments , 1999, IEEE J. Sel. Areas Commun..

[8]  Xiaodai Dong,et al.  Spectral and Energy Efficiency of Multi-Pair Massive MIMO Relay Network With Hybrid Processing , 2017, IEEE Transactions on Communications.

[9]  Brian L. Evans,et al.  ADC bit allocation under a power constraint for mmWave massive MIMO communication receivers , 2016, 2017 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP).

[10]  Josef A. Nossek,et al.  On Ultra-Wideband MIMO Systems with 1-bit Quantized Outputs: Performance Analysis and Input Optimization , 2007, 2007 IEEE International Symposium on Information Theory.

[11]  Chenyang Yang,et al.  Energy Efficiency Scaling Law of Massive MIMO Systems , 2017, IEEE Transactions on Communications.

[12]  Brian L. Evans,et al.  Resolution-Adaptive Hybrid MIMO Architectures for Millimeter Wave Communications , 2017, IEEE Transactions on Signal Processing.

[13]  Robert W. Heath,et al.  Low resolution adaptive compressed sensing for mmWave MIMO receivers , 2015, 2015 49th Asilomar Conference on Signals, Systems and Computers.

[14]  Robert W. Heath,et al.  Hybrid Architectures With Few-Bit ADC Receivers: Achievable Rates and Energy-Rate Tradeoffs , 2016, IEEE Transactions on Wireless Communications.

[15]  Robert W. Heath,et al.  MIMO Precoding and Combining Solutions for Millimeter-Wave Systems , 2014, IEEE Communications Magazine.

[16]  Ali H. Sayed,et al.  Active Antenna Selection in Multiuser MIMO Communications , 2007, IEEE Transactions on Signal Processing.

[17]  Kyungwhoon Cheun,et al.  Millimeter-wave beamforming as an enabling technology for 5G cellular communications: theoretical feasibility and prototype results , 2014, IEEE Communications Magazine.

[18]  Robert W. Heath,et al.  Near Maximum-Likelihood Detector and Channel Estimator for Uplink Multiuser Massive MIMO Systems With One-Bit ADCs , 2015, IEEE Transactions on Communications.

[19]  Ha H. Nguyen,et al.  Power Scaling Laws of Massive MIMO Full-Duplex Relaying With Hardware Impairments , 2018, IEEE Access.

[20]  Geoffrey Ye Li,et al.  An Overview of Massive MIMO: Benefits and Challenges , 2014, IEEE Journal of Selected Topics in Signal Processing.

[21]  Robert W. Heath,et al.  Capacity Analysis of One-Bit Quantized MIMO Systems With Transmitter Channel State Information , 2014, IEEE Transactions on Signal Processing.

[22]  Mohammad Gharavi-Alkhansari,et al.  Fast antenna subset selection in MIMO systems , 2004, IEEE Transactions on Signal Processing.

[23]  Shajahan Kutty,et al.  Beamforming for Millimeter Wave Communications: An Inclusive Survey , 2016, IEEE Communications Surveys & Tutorials.

[24]  Lifeng Wang,et al.  Safeguarding 5G wireless communication networks using physical layer security , 2015, IEEE Communications Magazine.

[25]  Xiqi Gao,et al.  Cellular architecture and key technologies for 5G wireless communication networks , 2014, IEEE Communications Magazine.

[26]  Erik G. Larsson,et al.  Massive MIMO for next generation wireless systems , 2013, IEEE Communications Magazine.

[27]  Robert W. Heath,et al.  An Overview of Signal Processing Techniques for Millimeter Wave MIMO Systems , 2015, IEEE Journal of Selected Topics in Signal Processing.

[28]  Michail Matthaiou,et al.  Power Scaling of Uplink Massive MIMO Systems With Arbitrary-Rank Channel Means , 2014, IEEE Journal of Selected Topics in Signal Processing.

[29]  Erik G. Larsson,et al.  Energy and Spectral Efficiency of Very Large Multiuser MIMO Systems , 2011, IEEE Transactions on Communications.

[30]  Arogyaswami Paulraj,et al.  Receive antenna selection for MIMO flat-fading channels: theory and algorithms , 2003, IEEE Trans. Inf. Theory.