Resource allocation in future green wireless networks : applications and challenges

Over the past few years, green radio communication has been an emerging topic since the footprint from the Information and Communication Technologies (ICT) is predicted to increase 7.3% annually and then exceed 14% of the global footprint by 2040. Moreover, the explosive progress of ICT, e.g., the fifth generation (5G) networks, has resulted in expectations of achieving 10-fold longer device battery lifetime, and 1000-fold higher global mobile data traffic over the fourth generation (4G) networks. Therefore, the demands for increasing the data rate and the lifetime while reducing the footprint in the next-generation wireless networks call for more efficient utilization of energy and other resources. To overcome this challenge, the concepts of small-cell, energy harvesting, and wireless information and power transfer networks can be evaluated as promising solutions for re-greening the world. In this dissertation, the technical contributions in terms of saving economical cost, protecting the environment, and guaranteeing human health are provided. More specifically, novel communication scenarios are proposed to minimize energy consumption and hence save economic costs. Further, energy harvesting (EH) techniques are applied to exploit available green resources in order to reduce carbon footprint and then protect the environment. In locations where implemented user devices might not harvest energy directly from natural resources, base stations could harvest-and-store green energy and then use such energy to power the devices wirelessly. However, wireless power transfer (WPT) techniques should be used in a wise manner to avoid electromagnetic pollution and then guarantee human health. To achieve all these aspects simultaneously, this thesis proposes promising schemes to optimally manage and allocate resources in future networks. Given this direction, in the first part, Chapter 2 mainly studies a transmission power minimization scheme for a two-tier heterogeneous network (HetNet) over frequency selective fading channels. In addition, the HetNet backhaul connection is unable to support a sufficient throughput for signaling an information exchange between two tiers. A novel idea is introduced in which the time reversal (TR) beamforming technique is used at a femtocell while zero-forcing-based beamforming is deployed at a macrocell. Thus, a downlink power minimizationscheme is proposed, and optimal closed-form solutions are provided. In the second part, Chapters 3, 4, and 5 concentrate on EH and wireless information and power transfer (WIPT) using RF signals. More specifically, Chapter 3 presents an overview of the recent progress in green radio communications and discusses potential technologies for some emerging topics on the platforms of EH and WPT. Chapter 4 develops a new integrated information and energy receiver architecture based on the direct use of alternating current (AC) for computation. It is shown that the proposed approach enhances not only the computational ability but also the energy efficiency over the conventional one. Furthermore, Chapter 5 proposes a novel resource allocation scheme in simultaneous wireless information and power transfer (SWIPT) networks where three crucial issues: power-efficient improvement, user-fairness guarantee, and non-ideal channel reciprocity effect mitigation, are jointly addressed. Hence, novel methods to derive optimal and suboptimal solutions are provided. In the third part, Chapters 6, 7, and 8 focus on simultaneous lightwave information and power transfer (SLIPT) for indoor applications, as a complementary technology to RF SWIPT. In this research, Chapter 6 investigates a hybrid RF/visible light communication (VLC) ultrasmall cell network where optical transmitters deliver information and power using the visible light, whereas an RF access point works as a complementary power transfer system. Thus, a novel resource allocation scheme exploiting RF and visible light for power transfer is devised. Chapter 7 proposes the use of lightwave power transfer to enable future sustainable Federated Learning (FL)-based wireless networks. FL is a new data privacy protection technique for training shared machine learning models in a distributed approach. However, the involvement of energy-constrained mobile devices in the construction of the shared learning models may significantly reduce their lifetime. The proposed approach can support the FL-based wireless network to overcome the issue of limited energy at mobile devices. Chapter 8 introduces a novel framework for collaborative RF and lightwave power transfer for wireless communication networks. The constraints on the transmission power set by safety regulations result in significant challenges to enhance the power transfer performance. Thus, the study of technologies complementary to conventional RF SWIPT is essential. To cope with this isue, this chapter proposes a novel collaborative RF and lightwave power transfer technology for next-generation wireless networks

Photonic Millimeter Wave Signal Generation and Transmission Over Hybrid Links in 5G Communication Networks

[ES] El estándar de quinta generación (5G) es la clave potencial para satisfacer el aumento exponencial en la demanda de nuevas aplicaciones, servicios y usuarios. La tecnología 5G ofrecerá una latencia extremadamente baja de 1 ms, una velocidad máxima de datos de 10 Gbit/s, una alta densidad de conexión de hasta 106 dispositivos/km2 y permitirá una alta movilidad de los dispositivos de hasta 500 km/h. En esta Tesis se proponen varias soluciones basadas en tecnologías habilitadoras para el despliegue de redes 5G. La arquitectura de la red de acceso de radio en la nube (C-RAN) se emplea junto con las técnicas de Fotónica de Microondas como una solución prometedora para generar y transmitir señales de ondas milimétricas (mmW) en la próxima generación de comunicaciones móviles. La tecnología radio sobre fibra (RoF) ha demostrado ser una buena opción para enfrentarse al desafío de la distribución inalámbrica mmW debido a la gran distancia de transmisión, el gran ancho de banda y la inmunidad a las interferencias electromagnéticas, entre algunas de las principales ventajas. Además, esta tecnología se puede ampliar con comunicaciones ópticas de espacio libre (FSO) en sistemas de radio sobre FSO (RoFSO) en las redes inalámbricas. En esta Tesis, las señales mmW se generan fotónicamente mediante modulación externa de doble banda lateral con supresión de portadora (CS-DSB) y se distribuyen a través de enlaces fronthaul híbridos RoF/FSO. Además, la generación múltiple de señales permite la distribución reconfigurable en canales multiplexados por división de longitud de onda (WDM) desde una oficina central hasta las estaciones base, y se ha evaluado el impacto de las turbulencias producidas en los canales FSO sobre las señales mmW generadas fotónicamente en términos de fluctuaciones de potencia y ruido de fase de la señal. Se propone la técnica de modulación directa de un láser (DML) como solución principal para la transmisión de datos a través de enlaces ópticos híbridos que emplean un esquema de multiplicación de frecuencias ópticas, es decir, CS-DSB, para la generación de señales de mmW. En concreto, se evalúan teórica y experimentalmente los esquemas de generación fotónica local y remoto de señales mmW y se comparan para su implementación práctica en la red frontal de la C-RAN y, además, se estudia experimentalmente el impacto de la distorsión armónica y de la intermodulación en la transmisión de datos. Igualmente, con el fin de obtener la capacidad que ofrece el DML en términos de ancho de banda, también se presenta una evaluación teórica y experimental del efecto de la dispersión de la fibra y el chirp sobre diferentes anchos de banda de señales de M-modulación de amplitud en cuadratura (QAM). No obstante, la Tesis también incluye otro enfoque para la transmisión de datos basado en el uso de otro modulador externo. En este caso, la demostración experimental de la generación de señales ópticas empleando CS-DSB y la transmisión de señales a través de fibra híbrida y red frontal FSO se completa con un enlace de antena que permite transmitir señales 5G 64/256-QAM. La investigación realizada con los sistemas CS-DSB y DSB también permiten comparar la robustez frente al desvanecimiento inducido por la dispersión cromática de la fibra. Además, se ha realizado una evaluación experimental impacto las turbulencias producidas en los canales FSO sobre las señales mmW generadas fotónicamente con diferentes distribuciones térmicas y se ha cuantificado la degradación de la señal de datos de acuerdo con las condiciones de la turbulencia. Como demostradores finales, esta Tesis incluye un sistema de transmisión full-dúplex que emplea señales 5G en enlace descendente (DL) a 39 GHz y en enlace ascendente (UL) a 37 GHz; y la transmisión de señales OFDM LTE de 60 GHz (DL) y 25 GHz (UL) sobre una infraestructura heterogénea de frontal óptico que consiste en fibra óptica de 10 km, un canal FSO de 100 m y un enlace de radio inalámbrico de 2 m.[CA] L'estàndard de quinta generació (5G) és la clau potencial per a satisfer l'augment exponencial en la demanda de noves aplicacions, serveis i usuaris. La tecnologia 5G oferirà una latència extremadament baixa d'1 ms, una velocitat màxima de dades de 10 Gbit/s, una alta densitat de connexió de fins a 106 dispositius/km2 i permetrà una alta mobilitat dels dispositius de fins a 500 km/h. En aquesta tesi es proposen diverses solucions basades en tecnologies habilitadores per al desplegament de xarxes 5G. L'arquitectura de la xarxa d'accés de ràdio en el núvol (CRAN) s'empra junt amb les tècniques de Fotònica de Microones com una solució prometedora per a generar i transmetre senyals d'ones mil·limètriques (mmW) en la pròxima generació de comunicacions mòbils. La tecnologia ràdio sobre fibra ( RoF) ha demostrat ser una bona opció per a enfrontar-se al desafiament de la distribució sense fil mmW a causa de la gran distància de transmissió, el gran ample de banda i la immunitat a les interferències electromagnètiques, entre alguns dels principals avantatges. A més, aquesta tecnologia es pot ampliar amb comunicacions òptiques d'espai lliure (FSO) en sistemes de ràdio sobre FSO (RoFSO) en les xarxes sense fil. En aquesta Tesi, els senyals mmW es generen fotònicament per mitjà de modulació externa de doble banda lateral amb supressió de portadora (CS-DSB) i es distribueixen a través d'enllaços frontals híbrids RoF/FSO.. A més, la generació múltiple de senyals permet la distribució reconfigurable en canals multiplexats per divisió de longitud d'ona ( WDM) des d'una oficina central fins a les estacions base, i s'ha avaluat l'impacte de les turbulències produïdes en els canals FSO sobre els senyals mmW generades fotònicament en termes de fluctuacions de potència i soroll de fase del senyal. Aquest treball proposa la tècnica de modulació directa d'un làser (DML) com solució principal per a la transmissió de dades a través d'enllaços òptics híbrids que fan servir un esquema de multiplicació de freqüències òptiques, és a dir, CS-DSB, per a la generació de senyals de mmW. En concret, s'avalua teòric i experimentalment els esquemes de generació fotònica local i remota de senyals mmW i es comparen per a la seua implementació pràctica a la xarxa frontal de la C-RAN i a més, s'estudia experimentalment l'impacte de la distorsió harmònica i de la intermodulació en la transmissió de dades. Igualment, amb el fi d'obtindre la capacitat que ofereix el DML en termes d'amplada de banda, també es presenta una avaluació teòrica i experimental de l'efecte de la dispersió de la fibra i el chirp sobre diferents amples de banda de senyals de M-modulació d'amplitud en quadratura (QAM). No obstant això, la Tesis també inclou altre enfocament per a la transmissió de dades basat amb l¿ús d'altre modulador extern. En aquest cas, la demostració experimental de la generació de senyals òptics emprant CS-DSB i la transmissió de senyals a través de fibra híbrida i xarxa frontal FSO es completa com un enllaç d'antena que permet transmetre senyals 5G 64/256-QAM. La investigació realitzada amb els sistemes CS-DSB i DSB també permet comparar la seua robustesa davant l¿esvaïment induït per la dispersió cromàtica. A més, s'ha avaluat experimentalment l'impacte de les turbulències produïdes en els canals FSO sobre els senyals mmW generades fotònicament amb diferents distribucions tèrmiques i s'ha quantificat la degradació del senyal de dades d'acord amb les condicions de la turbulència. Com a demostradors finals, aquesta Tesi inclou un sistema de transmissió full-dúplex que empra senyals 5G en enllaç descendent (DL) a 39 GHz i en enllaç ascendent (UL) a 37 GHz; i la transmissió de senyals OFDM LTE de 60 GHz (DL) i 25 GHz (UL) sobre una infraestructura heterogènia de frontal òptic que consisteix en fibra òptica de 10 km, un canal FSO de 100 m i un enllaç de ràdio sense fil de 2 m.[EN] The fifth generation (5G) standard is the potential key to meet the exponentially increasing demand of the emerging applications, services and mobile end users. 5G technology will offer an extremely low latency of 1 ms, peak data rate of 10 Gbit/s, high contention density up to 106 devices/km2 and enable high mobility up to 500 km/h. This Thesis proposes several solutions based on enabling technologies for deploying 5G networks. Cloud-radio access network (C-RAN) architecture is employed in conjunction with microwave photonics techniques as a promising solution to generate and transmit millimeter wave (mmW) signals in the next generation of mobile communications. Radio over fiber (RoF) has been demonstrated as a good option to face the challenge of mmW wireless distribution, due to long transmission distance, large bandwidth and immunity to electromagnetic interference, as some of the main advantages. Moreover, this technology can be extended with free-space optical (FSO) communications in Radio over FSO systems (RoFSO) as wireless networks. In this Thesis, mmW signals are photonically generated by carrier suppressed double sideband (CS-DSB) external modulation and distributed over hybrid RoF/FSO fronthaul links. Moreover, multiple generated signals allow reconfigurable distribution in wavelength-division multiplexed (WDM) channels from a central office to the base stations, and the impact of turbulent FSO channels on photonically generated mmW signals has been evaluated in terms of power signal fluctuations and phase noise. A directly modulated laser (DML) is proposed as a major solution for signal transmission over hybrid optical links employing optical frequency multiplication scheme, i.e. CS-DSB, for mmW signal generation. Moreover, local and remote photonic mmW signal generation schemes are theoretically and experimentally evaluated and compared for practical deployment in C-RAN fronthaul network while the impact of harmonic and intermodulation distortion on data transmission is also experimentally studied. Furthermore, for the sake of obtaining the DML usability in terms of bandwidth, theoretical and experimental evaluation of the effect of fiber dispersion and chirp over different M-quadrature amplitude modulation (QAM) signals bandwidth is also presented. Another data transmission approach based on the cascade of two external modulators is also employed in the Thesis. In this case, the experimental demonstration of optical signal generation employing CS-DSB and signal transmission over hybrid fiber and FSO fronthaul network is completed with a seamless antenna link leading to successful transmission of 64/256-QAM 5G signals. The CS-DSB and DSB schemes are also investigated for the sake of comparison in terms of robustness against fiber chromatic dispersion-induced fading. Furthermore, experimental evaluation of the impact of turbulent FSO links on photonically generated mmW signals with different thermal distributions has been performed and data signal degradation has been quantified according to the turbulence conditions. As final demonstrators, the Thesis includes a full-duplex transmission system employing 39 GHz downlink (DL) and 37 GHz uplink (UL) 5G signals over hybrid links; and 60 GHz (DL) and 25 GHz (UL) OFDM LTE signal transmission over an heterogeneous optical fronthaul infrastructure consisting of 10 km optical fiber, 100 m FSO channel and 2 m wireless radio link.I would like to acknowledge the financial support given by Research Excellence Award Programme GVA PROMETEO 2017/103 Future Microwave Photonics and European Network for High Performance Integrated Microwave Photonics (EUIMWP) CA16220.Vallejo Castro, L. (2022). Photonic Millimeter Wave Signal Generation and Transmission Over Hybrid Links in 5G Communication Networks [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/19025

Optical techniques for broadband in-building networks

Optical fibres, which can easily handle any bandwidth demand, have been rolled out to more than 32 million consumer’s homes and professional buildings worldwide up to 2010. The basic technological and economical challenges of fibre-to-the-home (FTTH) has been solved. The current FTTH technology can now providing baseband Gbit Ethernet and high definition TV services to the gates of homes. Thus, the bottleneck for delivery of broadband services to the end users is shifting from the access network to the in-building network. In the meantime, the need for high-capacity transmission between devices inside the building, e.g. between desktop PC and data services, are also rapidly increase. How to bring high bandwidth to the mobile terminals such as laptops, PDAs or cell phones as well as to the fixed terminals such as desktop PCs and HDTV equipment in an all-in-one network infrastructure is a challenge we are facing. Building on the flexibility of the wireless access networks and the latent vast bandwidth of a fibre infrastructure, radio-over-fibre (RoF) techniques have been proposed as a cost-effective solution to the future integrated broadband services in in-building networks. This thesis investigates techniques to deliver high data rate wireless services via in-building networks: high capacity RoF links employing optical frequency multiplication (OFM) and sub-carrier multiplexing (SCM) techniques, with single- or multi-carrier signal formats. The orthogonal frequency division multiplexing (OFDM) format is investigated for the RoF transmission system, particularly with regard to the optical system nonlinearity. For low-cost short-range optical backbone networks, RoF transmission over large-core diameter plastic optical fibre (POF) links has been studied, including the transmission of the WiMedia-compliant multiband OFDM UWB signal over bandwidth-limited large-core POF as well as a full-duplex bi-directional UWB transmission over POF. In order to improve the functionalities for delivery of wireless services of in-building networks, techniques to introduce flexibility into the network architecture and to create dynamic capacity allocation have been investigated. By employing optical switching techniques based on optical semiconductor amplifiers (SOA), an optically routed RoF system has been studied. The dynamic capacity allocation is addressed by investigating one-dimensional and two-dimensional routing using electrical SCM and optical wavelengths. In addition, next to RoF networking, this thesis explores techniques for wired delivery of baseband high capacity services over POF links by employing a multi-level signal modulation format, in particular discrete multi-tone (DMT) modulation. Transmission of 10 Gbit/s data over 1 mm core diameter PMMA POF links is demonstrated, as a competitor to more expensive fibre solutions such as silica single and multimode fibre. A record transmission rate of more than 40 Gbit/s is presented for POF whose core diameter is comparable with silica multimode fibre. Finally, from the network perspective, the convergence of wired and wireless multi-standard services into a single fibre-based infrastructure has been studied. Techniques have been designed and demonstrated for in-building networks, which can convey both high capacity baseband services and broadband radio frequency (RF) services over a POF backbone link. The multi-standard RoF signals carry different wireless services at different radio frequencies and with different bandwidths, including WiFi, WiMax, UMTS and UWB. System setups to carry them together over the same multimode optical fibre based network have been designed and experimentally shown. All the concepts, designs and system experiments presented in this thesis underline the strong potential of multimode (silica and plastic) optical fibre techniques for the delivery of broadband services to wired and wireless devices in in-building networks, in order to extend to the end user the benefits of the broadband FTTH networks which are being installed and deployed worldwide

Power Consumption Modeling and Analysis of Integrated Optical-Wireless Access Network

The integration of optical and wireless technologies at access networks are considered as a future solution which provide both high bandwidth and high mobility in an efficient way. GPON is a suitable candidate for optical backhaul due to the combination of higher data rates, greater split ratio and support for triple play services hence it offers maximum flexibility and cost advantages. On the other hand, recent developments of new radio access technologies and introduction of femtocell base stations provide the potential of offering broadband services and applications to everyone and everywhere. However, the power consumption of this network demands a particular attention because access networks are the largest contributor the network related electricity consumption. Therefore, in this paper we evaluate the power consumption of integrated optical-wireless access network which is based on independent ONU-BS architecture. We proposed a power consumption model for such network and the assessment has been done under different simulation scenarios. The constructed model will provide insight of the energy performance of the integrated access network so that in the network design process, focus can be done to the most energy saving strategies

Indoor Visible Light Communication:A Tutorial and Survey

Abstract With the advancement of solid-state devices for lighting, illumination is on the verge of being completely restructured. This revolution comes with numerous advantages and viable opportunities that can transform the world of wireless communications for the better. Solid-state LEDs are rapidly replacing the contemporary incandescent and fluorescent lamps. In addition to their high energy efficiency, LEDs are desirable for their low heat generation, long lifespan, and their capability to switch on and off at an extremely high rate. The ability of switching between different levels of luminous intensity at such a rate has enabled the inception of a new communication technology referred to as visible light communication (VLC). With this technology, the LED lamps are additionally being used for data transmission. This paper provides a tutorial and a survey of VLC in terms of the design, development, and evaluation techniques as well as current challenges and their envisioned solutions. The focus of this paper is mainly directed towards an indoor setup. An overview of VLC, theory of illumination, system receivers, system architecture, and ongoing developments are provided. We further provide some baseline simulation results to give a technical background on the performance of VLC systems. Moreover, we provide the potential of incorporating VLC techniques in the current and upcoming technologies such as fifth-generation (5G), beyond fifth-generation (B5G) wireless communication trends including sixth-generation (6G), and intelligent reflective surfaces (IRSs) among others

Estudi bibliomètric any 2014. Campus del Baix Llobregat: EETAC i ESAB

En el present informe s’analitza la producció científica de les dues escoles del Campus del Baix Llobregat, l’Escola d’Enginyeria de Telecomunicació i Aerospacial de Castelldefels (EETAC) i l’Escola Superior d’Agricultura de Barcelona (ESAB) durant el 2014.Postprint (author’s final draft