A Genetic Algorithm-based Beamforming Approach for Delay-constrained Networks

In this paper, we study the performance of initial access beamforming schemes in the cases with large but finite number of transmit antennas and users. Particularly, we develop an efficient beamforming scheme using genetic algorithms. Moreover, taking the millimeter wave communication characteristics and different metrics into account, we investigate the effect of various parameters such as number of antennas/receivers, beamforming resolution as well as hardware impairments on the system performance. As shown, our proposed algorithm is generic in the sense that it can be effectively applied with different channel models, metrics and beamforming methods. Also, our results indicate that the proposed scheme can reach (almost) the same end-to-end throughput as the exhaustive search-based optimal approach with considerably less implementation complexity

A survey on reconfigurable intelligent surfaces: wireless communication perspective

Using reconfigurable intelligent surfaces (RISs) to improve the coverage and the data rate of future wireless networks is a viable option. These surfaces are constituted of a significant number of passive and nearly passive components that interact with incident signals in a smart way, such as by reflecting them, to increase the wireless system's performance as a result of which the notion of a smart radio environment comes to fruition. In this survey, a study review of RIS-assisted wireless communication is supplied starting with the principles of RIS which include the hardware architecture, the control mechanisms, and the discussions of previously held views about the channel model and pathloss; then the performance analysis considering different performance parameters, analytical approaches and metrics are presented to describe the RIS-assisted wireless network performance improvements. Despite its enormous promise, RIS confronts new hurdles in integrating into wireless networks efficiently due to its passive nature. Consequently, the channel estimation for, both full and nearly passive RIS and the RIS deployments are compared under various wireless communication models and for single and multi-users. Lastly, the challenges and potential future study areas for the RIS aided wireless communication systems are proposed

Near-Field Communications: A Tutorial Review

Extremely large-scale antenna arrays, tremendously high frequencies, and new types of antennas are three clear trends in multi-antenna technology for supporting the sixth-generation (6G) networks. To properly account for the new characteristics introduced by these three trends in communication system design, the near-field spherical-wave propagation model needs to be used, which differs from the classical far-field planar-wave one. As such, near-field communication (NFC) will become essential in 6G networks. In this tutorial, we cover three key aspects of NFC. 1) Channel Modelling: We commence by reviewing near-field spherical-wave-based channel models for spatially-discrete (SPD) antennas. Then, uniform spherical wave (USW) and non-uniform spherical wave (NUSW) models are discussed. Subsequently, we introduce a general near-field channel model for SPD antennas and a Green's function-based channel model for continuous-aperture (CAP) antennas. 2) Beamfocusing and Antenna Architectures: We highlight the properties of near-field beamfocusing and discuss NFC antenna architectures for both SPD and CAP antennas. Moreover, the basic principles of near-field beam training are introduced. 3) Performance Analysis: Finally, we provide a comprehensive performance analysis framework for NFC. For near-field line-of-sight channels, the received signal-to-noise ratio and power-scaling law are derived. For statistical near-field multipath channels, a general analytical framework is proposed, based on which analytical expression for the outage probability, ergodic channel capacity, and ergodic mutual information are derived. Finally, for each aspect, the topics for future research are discussed.Comment: 45 pages, 35 figures; submitted to possible IEEE journa

Spatial modulation schemes and modem architectures for millimeter wave radio systems

The rapid growth of wireless industry opens the door to several use cases such as internet of things and device-to-device communications, which require boosting the reliability and the spectral efficiency of the wireless access network, while reducing the energy consumption at the terminals. The vast spectrum available in millimeter-wave (mmWave) frequency band is one of the most promising candidates to achieve high-speed communications. However, the propagation of the radio signals at high carrier frequencies suffers from severe path-loss which reduces the coverage area. Fortunately, the small wavelengths of the mmWave signals allow packing a large number of antennas not only at the base station (BS) but also at the user terminal (UT). These massive antenna arrays can be exploited to attain high beamforming and combining gains and overcome the path-loss associated with the mmWave propagation. In conventional (fully digital) multiple-input-multiple-output (MIMO) transceivers, each antenna is connected to a specific radio-frequency (RF) chain and high resolution analog-to-digital-converter. Unfortunately, these devices are expensive and power hungry especially at mmWave frequency band and when operating in large bandwidths. Having this in mind, several MIMO transceiver architectures have been proposed with the purpose of reducing the hardware cost and the energy consumption. Fully connected hybrid analog and digital precoding schemes were proposed in with the aim of replacing some of the conventional RF chains by energy efficient analog devices. These fully connected mapping requires many analog devices that leads to non-negligible energy consumption. Partially connected hybrid architectures have been proposed to improve the energy efficiency of the fully connected transceivers by reducing the number of analog devices. Simplifying the transceiver’s architecture to reduce the power consumption results in a degradation of the attained spectral efficiency. In this PhD dissertation, we propose novel modulation schemes and massive MIMO transceiver design to combat the challenges at the mmWave cellular systems. The structure of the doctoral manuscript can be expressed as In Chapter 1, we introduce the transceiver design challenges at mmWave cellular communications. Then, we illustrate several state of the art architectures and highlight their limitations. After that, we propose scheme that attains high-energy efficiency and spectrum efficiency. In chapter 2, first, we mathematically describe the state of the art of the SM and highlight the main challenges with these schemes when applied at mmWave frequency band. In order to combat these challenges (for example, high cost and high power consumption), we propose novel SM schemes specifically designed for mmWave massive MIMO systems. After that, we explain how these schemes can be exploited in attaining energy efficient UT architecture. Finally, we present the channel model, systems assumptions and the transceiver devices power consumption models. In chapter 3, we consider single user SM system. First, we propose downlink (DL) receive SM (RSM) scheme where the UT can be implemented with single or multiple radio-frequency chains and the BS can be fully digital or hybrid architecture. Moreover, we consider different precoders at the BS and propose low complexity and efficient antenna selection schemes for narrowband and wideband transmissions. After that, we propose joint uplink-downlink SM scheme where we consider RSM in the DL and transmit SM (TSM) in the UL based on energy efficient hybrid UT architecture. In chapter 4, we extend the SM system to the multi-user case. Specifically, we develop joint multi-user power allocation, user selection and antenna selection algorithms for the broadcast and the multiple access channels. Chapter 5 is presented for concluding the thesis and proposing future research directions.Considerando los altos requerimientos de los servicios de nueva generación, las infraestructuras de red actual se han visto obligadas a evolucionar en la forma de manejar los diferentes recursos de red y computación. Con este fin, nuevas tecnologías han surgido para soportar las funcionalidades necesarias para esta evolución, significando también un gran cambio de paradigma en el diseño de arquitecturas para la futura implementación de redes.En este sentido, este documento de tesis doctoral presenta un análisis sobre estas tecnologías, enfocado en el caso de redes inter/intra Data Centre. Por consiguiente, la introducción de tecnologías basadas en redes ópticas ha sido estudiada, con el fin de identificar problemas actuales que puedan llegar a ser solucionados mediante el diseño y aplicación de nuevas técnicas, asimismo como a través del desarrollo o la extensión de los componentes de arquitectura de red.Con este propósito, se han definido una serie de propuestas relacionadas con aspectos cruciales, así como el control de dispositivos ópticos por SDN para habilitar el manejo de redes híbridas, la necesidad de definir un mecanismo de descubrimiento de topologías ópticas capaz de exponer información precisa, y el analizar las brechas existentes para la definición de una arquitectura común en fin de soportar las comunicaciones 5G.Para validar estas propuestas, se han presentado una serie de validaciones experimentales por medio de escenarios de prueba específicos, demostrando los avances en control, orquestación, virtualización y manejo de recursos con el fin de optimizar su utilización. Los resultados expuestos, además de corroborar la correcta operación de los métodos y componentes propuestos, abre el camino hacia nuevas formas de adaptar los actuales despliegues de red respecto a los desafíos definidos en el inicio de una nueva era de las telecomunicaciones.Postprint (published version

Investigating the data rate in reconfigurable intelligent surfaces assisted wireless communication

In the realm of wireless communications, reconfigurable intelligent surfaces (RIS) offer network providers the capability to manage the behaviour of electromagnetic signals, encompassing their scattering, reflection, and refraction properties. Numerous research findings have underscored RIS’s effectiveness in controlling wireless wave attributes, such as amplitude and phase, without necessitating intricate equalization and decoding at the receiver’s end. However, it’s crucial to note that configuring the surface in practical scenarios with frequency-selective fading channels should be carefully addressed across the entire bandwidth. This entails considering a wideband orthogonal frequency division multiplexing (OFDM) communication system that is based on a practical RIS configuration, involving distinct phase shifts for each element on the surface. In this thesis, we propose a communication setup to investigate the user data rate enhancement with the aid of RIS surface using practical phase shift model for multi-bit RIS phase resolutions. It is observed that the achievable data rate enhances with higher bit resolutions but the cost of hardware complexity. The effects of mutual coupling (MC) due to the large RIS surface and the electromagnetic interference (EMI) due to the unavoidable signals from external sources are well investigated on the performance data rate. The MC and EMI degrade the achievable rate so, the RIS must be aware of such signal impairment parameters. Furthermore, we have extended the study of the performance of the achievable data rate for multi-users in single-input-single-output (SISO) wideband based-RIS system with single antenna at the access point (AP) and each user. The propagation environment was assumed to have both line-of-sight (LoS) and non-line-of-sight (NLoS) channels so, it is more realistic and practical. Different RIS algorithms are studied in both LoS and NLoS channels scenarios taking into considerations the computational complexity and run time. The semidefinite relaxation scheme shows higher performance than the other schems but at the cost of computational complexity and run time consequently, the thesis proposes low complex with comparable performance iterative power method that adopts codebook approach. The RIS demonstrated significant performance data rate not only in communication but also in localization. The RIS-enabled localization has been investigated in the near and far-field regimes using realistic RIS phase shift model that considers the phase and amplitude variations. We introduced an analysis of Fisher information using a straightforward expression for the Fisher information matrix (FIM), illustrating how the position error bound (PEB) is influenced by the phase profiles of RIS. We employed three types of RIS phase profiles—random, directional, and positional configurations—to showcase the impact of RIS on localization and communication within the near-field range. These profiles were designed considering both the amplitude and phase responses of the RIS, utilizing a practical phase-dependent amplitude model. The random profile ensures a uniform signal-to-noise ratio (SNR) across the deployment area, while the directional and positional profiles enhance SNR towards the user’s location. Additionally, we devised a straightforward localization scheme to simplify the maximum likelihood (ML) estimator’s complexity. In the near-field region, the achievable data rate diminishes with distance, mirroring the gradual increase in localization error as distance from the RIS grows. Both the achievable data rate and localization error exhibit subpar performance when employing the RIS phase-dependent amplitude model with amplitude values less than one. Consequently, the widespread assumption of unity amplitude in the RIS phase shift model, as commonly seen in literature, leads to overly optimistic and inaccurate results in localization and communication performance. Simulation results have shown the importance of utilizing RIS technology in both communication and localization. Finally, we have carried out RIS measurements field in the mast lab to configure the test bed hardware of 64×64 RIS elements in order to show the capability of such new technology in improving the signal strength and coverage