Hybrid precoding has been envisaged as an attractive alternative to fully digital precoding in massive multiple-input-multiple-output (mMIMO) systems, where it can ultimately reduce the cost and the power consumption while maintaining an acceptable sum rate. Within this context, deep learning (DL) is proposed as an optimization tool to realize this. However, most of the existing DL based hybrid precoding solutions are based on the convolutional neural networks (CNNs), which have inductive bias that limits the learning capability of the highly stochastic massive MIMO channel. Conversely, the present contribution proposes a novel DL based hybrid precoder that can achieve an improved performance at a reduced computation time compared to the CNN based techniques. This is achieved through the design of a Perceiver Neural Network (PNN) architecture for hybrid precoding, where the PNN accepts a noisy channel matrix as an input and produces the analog precoder and combiners as an output. Also, the proposed architecture learns to reshape the input data in order to achieve the best accuracy through a novel trainable reshaping module. Our design involves an offline phase, in which we build our realistic ray tracing based massive MIMO dataset to train our Perceiver-based hybrid precoder (PBHP). In this context, we conduct extensive experiments to compare the PBHP with a CNN-based hybrid precoder (CNN-HP). It is extensively shown that the proposed PBHP outperforms the CNN-HP in terms of both accuracy and inference time. Moreover, the PBHP is more robust when the transmit power is low and the number of antennas is large. Finally, the offered results demonstrate that the PBHP exhibits a drastically less inference time (by nearly an order of magnitude) than the CNN-HP, especially for higher number of antennas, rendering it a promising candidate for the next-generation wireless networks.

Visible Light Communication (VLC) is a promising enabling technology for the next-generation wireless networks, as it complements radio-frequency (RF)-based communications by providing wider bandwidth, higher data rates, and immunity to interference from electromagnetic sources. However, due to its unique characteristics, VLC is highly sensitive to the line-of-sight (LoS) blockage. Recently, intelligent reflecting surface (IRS) has been proposed as an innovative solution that dynamically reconfigures the wireless environment. The present contribution proposes a two-stage resource management framework in an indoor VLC system: In the first stage, a maximum possible fairness (MPF) algorithm is presented in order to maximize the fairness amongst the users. In the second stage, deep Q-learning is exploited in order to maximize the overall spectral efficiency (SE). The corresponding numerical results have shown that the proposed DQL-MPF framework exhibits superior performance in terms of the overall SE, achieved at fast convergence rate. More specifically, when the noise power is high and the number of users is relatively large, the DQL-MPF algorithm achieves a more than tenfold overall SE compared to the Baseline scheme. Moreover, the synergy between the MPF and the DQL algorithms is investigated. To this end, we demonstrate that the MPF algorithm maximizes the fairness amongst the users while the DQL algorithm maximizes the overall SE and improves the robustness against the noise.

Visible light communication (VLC) has been introduced as a key enabler for high-data rate wireless services in future wireless communication networks. In addition to this, it was also demonstrated recently that non-orthogonal multiple access (NOMA) can further improve the spectral efficiency of multi-user VLC systems. In this context and owing to the significantly promising potential of artificial intelligence in wireless communications, the present contribution proposes a deep Q-learning (DQL) framework that aims to optimize the performance of an indoor NOMA-VLC downlink network. In particular, we formulate a joint power allocation and LED transmission angle tuning optimization problem, in order to maximize the average sum rate and the average energy efficiency. The obtained results demonstrate that our algorithm offers a noticeable performance enhancement into the NOMA-VLC systems in terms of average sum rate and average energy efficiency, while maintaining the minimum convergence time, particularly for higher number of users. Furthermore, considering a realistic downlink VLC network setup, the simulation results have shown that our algorithm outperforms the genetic algorithm (GA) and the differential evolution (DE) algorithm in terms of average sum rate, and offers considerably less run-time complexity.