Hybrid Beamforming for Millimeter Wave Multi-User MIMO Systems Using Learning Machine

Hybrid beamforming (HBF) design is a crucial stage in millimeter wave (mmWave) multi-user multi-input multi-output (MU-MIMO) systems. However, conventional HBF methods are still with high complexity and strongly rely on the quality of channel state information. We propose an extreme learning machine (ELM) framework to jointly optimize transmitting and receiving beamformers. Specifically, to provide accurate labels for training, we first propose a factional-programming and majorization-minimization based HBF method (FP-MM-HBF). Then, an ELM based HBF (ELM-HBF) framework is proposed to increase the robustness of beamformers. Both FP-MM-HBF and ELM-HBF can provide higher system sum-rate compared with conventional methods. Moreover, ELM-HBF cannot only provide robust HBF performance but also consume very short computation time.

[1]  Ming Xiao,et al.  Decentralized Multi-Task Learning Based on Extreme Learning Machines , 2019, ArXiv.

[2]  Tao Jiang,et al.  Deep learning for wireless physical layer: Opportunities and challenges , 2017, China Communications.

[3]  Dianhui Wang,et al.  Extreme learning machines: a survey , 2011, Int. J. Mach. Learn. Cybern..

[4]  Prabhu Babu,et al.  Transmit Waveform/Receive Filter Design for MIMO Radar With Multiple Waveform Constraints , 2018, IEEE Transactions on Signal Processing.

[5]  Ming Xiao,et al.  Millimeter Wave Communications for Future Mobile Networks , 2017, IEEE Journal on Selected Areas in Communications.

[6]  Shuangfeng Han,et al.  Reliable Beamspace Channel Estimation for Millimeter-Wave Massive MIMO Systems with Lens Antenna Array , 2017, IEEE Transactions on Wireless Communications.

[7]  Bin Cao,et al.  Artificial Intelligence Aided Joint Bit Rate Selection and Radio Resource Allocation for Adaptive Video Streaming over F-RANs , 2020, IEEE Wireless Communications.

[8]  Xiaodai Dong,et al.  Hybrid Block Diagonalization for Massive Multiuser MIMO Systems , 2015, IEEE Transactions on Communications.

[9]  Wei Yu,et al.  Optimization of MIMO Device-to-Device Networks via Matrix Fractional Programming: A Minorization–Maximization Approach , 2018, IEEE/ACM Transactions on Networking.

[10]  Ahmet M. Elbir,et al.  CNN-Based Precoder and Combiner Design in mmWave MIMO Systems , 2019, IEEE Communications Letters.

[11]  Khaled Ben Letaief,et al.  Alternating Minimization Algorithms for Hybrid Precoding in Millimeter Wave MIMO Systems , 2016, IEEE Journal of Selected Topics in Signal Processing.

[12]  Martin Haardt,et al.  Zero-forcing methods for downlink spatial multiplexing in multiuser MIMO channels , 2004, IEEE Transactions on Signal Processing.

[13]  Robert W. Heath,et al.  Hybrid MMSE Precoding and Combining Designs for mmWave Multiuser Systems , 2017, IEEE Access.

[14]  Jing Xing,et al.  Autoencoder Neural Network Based Intelligent Hybrid Beamforming Design for mmWave Massive MIMO Systems , 2020, IEEE Transactions on Cognitive Communications and Networking.

[15]  Fumiyuki Adachi,et al.  Deep-Learning-Based Millimeter-Wave Massive MIMO for Hybrid Precoding , 2019, IEEE Transactions on Vehicular Technology.

[16]  Ming Xiao,et al.  Learning-Based Hybrid Beamforming Design for Full-Duplex Millimeter Wave Systems , 2020, IEEE Transactions on Cognitive Communications and Networking.

[17]  Ahmet M. Elbir,et al.  Hybrid Precoding for Multiuser Millimeter Wave Massive MIMO Systems: A Deep Learning Approach , 2019, IEEE Transactions on Vehicular Technology.

[18]  Ahmed Alkhateeb,et al.  Deep Learning for Direct Hybrid Precoding in Millimeter Wave Massive MIMO Systems , 2019, 2019 53rd Asilomar Conference on Signals, Systems, and Computers.

[19]  Ahmet M. Elbir,et al.  Hybrid Precoding for Multi-User Millimeter Wave Massive MIMO Systems: A Deep Learning Approach , 2019, ArXiv.