Propagation channel characterisation and modelling for high-speed train communication systems

High-mobility scenarios, e.g., High-Speed Train (HST) scenarios, are expected to be typical scenarios for the Fifth Generation (5G) communication systems. With the rapid development of HSTs, an increasing volume of wireless communication data is required to be transferred to train passengers. HST users demand high network capacity and reliable communication services regardless of their locations or speeds, which are beyond the capability of current HST communication systems. The features of HST channels are significantly different from those of low-mobility cellular communication systems. For a proper design and evaluation of future HST wireless communication systems, we need accurate channel models that can mimic the underlying channel characteristics, especially the non-stationarity for different HST scenarios. Inspired by the lack of such accurate HST channel models in the literature, this PhD project is devoted to the modelling and simulation of non-stationary Multiple-Input Multiple-Output (MIMO) channels for HST communication systems. In this thesis, we first give a comprehensive review of the measurement campaigns conducted in different HST scenarios and address the recent advances in HST channel models. We also highlight the key challenges of HST channel measurements and models. Then, we study the characterisation of non-stationary channels and propose a theoretical framework for deriving the statistical properties of these channels. HST wireless communication systems encounter different channel conditions due to the difference of surrounding geographical environments or scenarios. HST channel models in the literature have either considered large-scale parameters only and/or neglected the non-stationarity of HST channels and/or only consider one of the HST scenarios. Therefore, we propose a novel generic non-stationary Geometry-Based Stochastic Model (GBSM) for wideband MIMO HST channels in different HST scenarios, i.e., open space, viaduct, and cutting. The corresponding simulation model is then developed with angular parameters calculated by the Modified Method of Equal Area (MMEA). The system functions and statistical properties of the proposed channel models are thoroughly studied. The proposed generic non-stationary HST channel models are verified by measurements in terms of stationary time for the open space scenario and the Autocorrelation Function (ACF), Level Crossing Rate (LCR), and stationary distance for the viaduct and cutting scenarios. Transmission techniques which are capable of utilising Three-Dimensional (3D) spatial dimensions are significant for the development of future communication systems. Consequently, 3D MIMO channel models are critical for the development and evaluation of these techniques. Therefore, we propose a novel 3D generic non-stationary GBSM for wideband MIMO HST channels in the most common HST scenarios. The corresponding simulation model is then developed with angular parameters calculated by the Method of Equal Volume (MEV). The proposed models considers several timevarying channel parameters, such as the angular parameters, the number of taps, the Ricean K-factor, and the actual distance between the Transmitter (Tx) and Receiver (Rx). Based on the proposed generic models, we investigate the impact of the elevation angle on some of the channel statistical properties. The proposed 3D generic models are verified using relevant measurement data. Most standard channel models in the literature, like Universal Mobile Telecommunications System (UMTS), COST 2100, and IMT-2000 failed to introduce any of the HST scenarios. Even for the standard channel models which introduced a HST scenario, like IMT-Advanced (IMT-A) and WINNER II channel models, they offer stationary intervals that are noticeably longer than those in measured HST channels. This has inspired us to propose a non-stationary IMT-A channel model with time-varying parameters including the number of clusters, powers, delays of the clusters, and angular parameters. Based on the proposed non-stationary IMT-A channel model, important statistical properties, i.e., the time-variant spatial Cross-correlation Function (CCF) and time-variant ACF, are derived and analysed. Simulation results demonstrate that the stationary interval of the developed non-stationary IMT-A channel model can match that of relevant HST measurement data. In summary, the proposed theoretical and simulation models are indispensable for the design, testing, and performance evaluation of 5G high-mobility wireless communication systems in general and HST ones in specific

Channel Measurements and Models for High-Speed Train Communication Systems: A Survey

The recent development of high-speed trains (HSTs) as an emerging high mobility transportation system, and the growing demands of broadband services for HST users, introduce new challenges to wireless communication systems for HSTs. Accurate and efficient channel models considering both large-scale and non-stationary small-scale fading characteristics are crucial for the design, performance evaluation, and parameter optimization of HST wireless communication systems. However, the characteristics of the underlying HST channels have not yet been sufficiently investigated. This paper first provides a comprehensive review of the measurement campaigns conducted in different HST scenarios and then addresses the recent advances in HST channel models. Finally, key challenges of HST channel measurements and models are discussed and several research directions in this area are outlined

Propagation and Wireless Channel Modeling Development on Wide-Sense Vehicle-to-X Communications

The need for improving the safety and the efficiency of transportation systems has become of extreme importance. In this regard, the concept of vehicle-to-X (V2X) communication has been introduced with the purpose of providing wireless communication technology in vehicular networks. Not like the traditional views, the wide-sense V2X (WSV2X) communications in this paper are defined by including not only vehicle-to-vehicle (V2V) and vehicle-to-infrastructure (V2I) communications but also train-to-X (T2X) communications constituted of train-to-train (T2T) and train-to-infrastructure (T2I) communications. All the information related to the wide-sense V2X channels, such as the standardization, scenarios, characters, and modeling philosophies, is organized and summarized to form the comprehensive understanding of the development of the WSV2X channels

Measurements and analysis of large-scale fading characteristics in curved subway tunnels at 920 MHz, 2400 MHz, and 5705 MHz

ave propagation characteristics in curved tunnels are of importance for designing reliable communications in subway systems. This paper presents the extensive propagation measurements conducted in two typical types of subway tunnels—traditional arched “Type I” tunnel and modern arched “Type II” tunnel—with300- and 500-m radii of curvature with different configurations—horizontal and vertical polarizations at 920, 2400, and 5705 MHz, respectively. Based on the measurements, statistical metrics of propagation loss and shadow fading (path-loss exponent, shadow fading distribution, autocorrelation, and cross-correlation) in all the measurement cases are extracted. Then, the large-scale fading characteristics in the curved subway tunnels are compared with the cases of road and railway tunnels, the other main rail traffic scenarios, and some “typical” scenarios to give a comprehensive insight into the propagation in various scenarios where the intelligent transportation systems are deployed. Moreover, for each of the large-scale fading parameters, extensive analysis and discussions are made to reflect the physical laws behind the observations. The quantitative results and findings are useful to realize intelligent transportation systems in the subway system

Channel Measurements and Models for High-Speed Train Wireless Communication Systems in Tunnel Scenarios: A Survey

The file attached to this record is the author's final peer reviewed version. The Publisher's final version can be found by following the DOI link.The rapid developments of high-speed trains (HSTs) introduce new challenges to HST wireless communication systems. Realistic HST channel models play a critical role in designing and evaluating HST communication systems. Due to the length limitation, bounding of tunnel itself, and waveguide effect, channel characteristics in tunnel scenarios are very different from those in other HST scenarios. Therefore, accurate tunnel channel models considering both large-scale and small-scale fading characteristics are essential for HST communication systems. Moreover, certain characteristics of tunnel channels have not been investigated sufficiently. This article provides a comprehensive review of the measurement campaigns in tunnels and presents some tunnel channel models using various modeling methods. Finally, future directions in HST tunnel channel measurements and modeling are discussed

Performance investigation of spatial modulation systems under realistic channel models

In order to fulfil the explosive demand for convenient wireless data access, novel wireless technologies such as the multiple-input-multiple-output (MIMO) have widely been used to improve the link reliability and capacity of wireless communication systems. In recent years, a new MIMO technology named the spatial modulation (SM) has attracted signi cant research interest due to its reported enhancement on the system performance with the reasonable system complexity. Before a new technology comes into real use, it is necessary to comprehensively evaluate its performance under different scenarios. In this thesis, we investigate the performance of SM systems under some important realistic scenarios for future wireless communications, such as the vehicle-to-vehicle (V2V), the high-speed train (HST), and the massive MIMO scenarios. Firstly, the bit error rate (BER) performance of SM systems under a novel threedimensional (3D) geometry based stochastic model (GBSM) for V2V MIMO channels is investigated by both theoretical analysis and system simulations. The impacts of vehicle tra c density (VTD), Doppler effect, and 3D feature on the BER performance of SM systems are thoroughly studied. In addition, other MIMO technologies, such as the vertical Bell Labs layered space-time (V-BLAST), the Alamouti scheme are compared with SM under different simulation settings. Secondly, the BER performance of SM systems is studied under a non-stationary wideband HST GBSM considering the non-ideal channel estimation case. The timevarying behaviour of the channel and its impact on the performance of SM systems are comprehensively investigated. The accurate theoretical BER expression of SM systems under a non-stationary wideband HST channels with non-ideal channel estimation is derived. A novel statistic property named stationary interval in terms of the space-time correlation function (STCF) is introduced in order to clearly explain all theoretical and simulation results. Thirdly, the performance of SM systems is evaluated under a Kroneck-based massive MIMO channel model. As a massive MIMO system employs large numbers of antennas, antenna elements are distributed over a wide range. Thus, different antenna elements may observe different sets of clusters. How this phenomenon affects the performance of SM systems is investigated by considering a survival probability of clusters, which abstracts the birth-death process of each cluster in the channel model. Moreover, the performance of SM systems is also compared with that of other MIMO technologies under the massive MIMO channel model. In summary, all research works in this thesis have considered realistic MIMO channel models, which are meaningful for the test, performance evaluation, and implementation of SM technology for future advanced wireless communications systems

Cooperative Radio Communications for Green Smart Environments

The demand for mobile connectivity is continuously increasing, and by 2020 Mobile and Wireless Communications will serve not only very dense populations of mobile phones and nomadic computers, but also the expected multiplicity of devices and sensors located in machines, vehicles, health systems and city infrastructures. Future Mobile Networks are then faced with many new scenarios and use cases, which will load the networks with different data traffic patterns, in new or shared spectrum bands, creating new specific requirements. This book addresses both the techniques to model, analyse and optimise the radio links and transmission systems in such scenarios, together with the most advanced radio access, resource management and mobile networking technologies. This text summarises the work performed by more than 500 researchers from more than 120 institutions in Europe, America and Asia, from both academia and industries, within the framework of the COST IC1004 Action on "Cooperative Radio Communications for Green and Smart Environments". The book will have appeal to graduates and researchers in the Radio Communications area, and also to engineers working in the Wireless industry. Topics discussed in this book include: • Radio waves propagation phenomena in diverse urban, indoor, vehicular and body environments• Measurements, characterization, and modelling of radio channels beyond 4G networks• Key issues in Vehicle (V2X) communication• Wireless Body Area Networks, including specific Radio Channel Models for WBANs• Energy efficiency and resource management enhancements in Radio Access Networks• Definitions and models for the virtualised and cloud RAN architectures• Advances on feasible indoor localization and tracking techniques• Recent findings and innovations in antenna systems for communications• Physical Layer Network Coding for next generation wireless systems• Methods and techniques for MIMO Over the Air (OTA) testin

Diseño y evaluación de nuevas formas e onda para comunicaciones de alta movilidad

Programa Oficial de Doutoramento en Tecnoloxías da Información e Comunicación en Redes Móbiles. 553V01[Resumo] Os servizos multimedia e de datos experimentaron un crecemento continuo nos últimos anos e espérase que crezan aínda máis nos anos seguintes. A xente está a usar cada vez máis os seus dispositivos móbiles para acceder a servizos baseados en datos para fins relacionados co traballo, entretemento ou socialización en liña. Ademais, as comunicacións masivas de tipo máquina tamén están en ascenso (por exemplo, as comunicacións en transporte e loxística, sensores, Internet das cousas, etc.), e serán moi importantes para a nova xeración de sistemas de comunicacións sen fíos. Para afrontar o aumento esperado no uso de servizos multimedia e baseado en datos, así como para soportar novos casos de uso que hoxe non son posibles, unha nova xeración de redes sen fíos é necesaria. Para iso, espérase que os sistemas de comunicación sen fíos 5G traian as melloras necesarias: maiores taxas de datos, baixas latencias, mellor eficiencia enerxética, alta fiabilidade, etc. O coñecemento das características da canle sen fíos é fundamental para a planificación das redes de comunicación sen fíos e o deseño de transceptores. Como primeiro paso, centramos este traballo na caracterización completa da canle para diferentes escenarios, como son os trens de alta velocidade, metro e comunicacións vehículo a infraestrutura en estradas. A canle caracterizouse mediante a avaliación da relación sinal a ruído, a perda de traxecto (path loss) e os chamados parámetros condensados da canle (por exemplo, o factor K, o perfil potencia-retardo (power delay profile) e a densidade espectral de potencia Doppler. Ademais, para a nova interface aérea das redes 5G, unha das principais cuestións foi a forma de onda a usar. Finalmente, o 3rd Generation Partnership Project (3GPP) decidiu usar a tecnoloxía de multiplexación por división de frecuencias ortogonais (OFDM polas súas siglas en inglés). Isto semella unha elección natural debido ás moitas vantaxes de OFDM e que tamén é a técnica de modulación empregada nas redes 4G. Con todo, nos últimos anos, esquemas multiportadora baseados en bancos de filtros (FBMC polas súas siglas en inglés) recibiron unha grande atención como alternativa a OFDM debido ás súas vantaxes: non utilizan un prefixo cíclico (proporcionan unha maior eficiencia espectral), os usuarios non precisan ser sincronizados no enlace ascendente, e un mellor rendemento teórico en contornas de alta velocidade debido a unha menor interferencia entre portadoras. Neste traballo comparamos experimentalmente o rendemento de FBMC e OFDM en contornas de alta velocidade. Tamén analizamos o rendemento de FBMC e OFDM no caso de uso práctico dun vehículo aéreo lixeiro pilotado remotamente. A maior parte do traballo realizado nesta tese requiriu o deseño e desenvolvemento do chamado GTEC 5G Simulator, que foi usado en conxunto co GTEC Testbed para realizar a maior parte das campañas de medicións e avaliacións de rendemento mediante transmisións polo aire.[Resumen] Los servicios multimedia y basados en datos experimentaron un crecimiento sin interrupciones en los últimos años, y se espera que crezcan aún más en los años siguientes. Las personas utilizan cada vez más sus dispositivos móviles para acceder a los servicios basados en datos con fines relacionados con el trabajo, el entretenimiento o la socialización en línea. Además, las comunicaciones masivas de tipo máquina también están en aumento (por ejemplo, comunicaciones en transporte y logística, sensores, Internet de las cosas, etc.) y serán muy importantes para la nueva generación de sistemas de comunicaciones inalámbricos. Para hacer frente al aumento esperado en el uso de servicios multimedia y basados en datos, así como para soportar nuevos casos de uso que no son posibles hoy en día, se requiere una nueva generación de sistemas inalámbricos. Para esto, se espera que los sistemas de comunicación inalámbrica 5G aporten las mejoras necesarias: mayores tasas de datos, menores latencias, mejor eficiencia energética, alta fiabilidad, etc. El conocimiento de las características del canal inalámbrico es fundamental para la planificación de redes de comunicación inalámbricas y el diseño de transceptores. Como primer paso, centramos este trabajo en la caracterización completa del canal para diferentes escenarios, tales como trenes de alta velocidad, metro y comunicaciones vehículo a infraestructura en carreteras. El canal se caracterizó por medio de la evaluación de la relación señal a ruido, la pérdida de trayecto (path loss) y los llamados parámetros condensados de canal (por ejemplo, el factor K, el perfil potencia-retardo (power delay profile) y la densidad espectral de potencia Doppler). Además, para la nueva interfaz aérea de las redes 5G, una de las preguntas principales ha sido la forma de onda a usar. Finalmente, el 3rd Generation Partnership Project (3GPP) decidió usar la tecnología de multiplexación por división de frecuencias ortogonales (OFDM por sus siglas en inglés). Esta es una elección lógica, debido a las muchas ventajas exhibidas por OFDM y dado que también es la técnica de modulación empleada en las redes 4G. Sin embargo, en los últimos años, los esquemas multiportadora basados en bancos de filtros (FBMC por sus siglas en inglés) han recibido una gran atención como una alternativa a OFDM debido a sus ventajas: no usan un prefijo cíclico (lo que proporciona una mayor eficiencia espectral), los usuarios no necesitan sincronizarse en el enlace ascendente, y un mejor rendimiento teórico en escenarios de alta velocidad debido a una menor interferencia entre subportadoras. En este trabajo comparamos experimentalmente el rendimiento de FBMC y OFDM en entornos de alta velocidad. También analizamos el rendimiento de FBMC y OFDM en el caso de uso práctico de un vehículo aéreo ligero tripulado remotamente. La mayor parte del trabajo llevado a cabo en esta tesis requirió el diseño y desarrollo del denominado GTEC 5G Simulator, que se utilizó junto con el GTEC Testbed para realizar la mayoría de las campañas de medidas y evaluaciones de rendimiento por medio de transmisiones por aire.[Abstract] Multimedia and data-based services experienced a non-stopping growth over the last few years and are expected to grow even more in the following years. People are using more and more their mobile devices to access data-based services for work-related purposes, entertainment or online socialization. Moreover, massive machine-type communications are also on the rise (e.g., transport and logistics communications, sensors, Internet of Things, etc.), and will be very important for the new generation of wireless communication systems. To cope with the expected increase in the usage of multimedia and data-based services, as well as to support new use cases which are not possible today, a new generation of wireless systems is required. For this, 5G wireless communication systems are expected to bring the necessary improvements: higher data rates, lower latencies, better energy efficiency, high reliability, etc. Knowledge of the wireless channel characteristics is fundamental for the planning of wireless communication networks and transceivers design. As a first step, this work centered in the channel characterization for different scenarios such as high-speed trains, subways, and vehicle-to-infrastructure in roads. The channel was characterized by means of assessing the signal-to-noise ratio, the path loss, and the so-called channel condensed parameters (e.g., the K-factor, the power delay profile, and the Doppler power spectral density). Moreover, for the new air interface of 5G networks, one of the main questions was the waveform to be used. Finally, the 3rd Generation Partnership Project (3GPP) decided to use orthogonal frequencydivision multiplexing (OFDM). This seems a natural choice due to the many advantages exhibited by OFDM and it is also the modulation technique employed by 4G networks. However, over the last few years, schemes based on filter bank multicarrier (FBMC) using quadrature amplitude modulation have received a great attention as an alternative to OFDM due to their advantages: they do not use a cyclic prefix (thus providing a higher bandwidth efficiency), users do not need to be synchronized in the uplink, and they achieve a theoretical better performance in high-speed scenarios due to a lower inter-carrier interference. In this work, we have experimentally compared the performance of FBMC versus OFDM in high-speed scenarios. We have also analyzed the performance of FBMC versus OFDM in the practical use case of a lightweight remotely piloted aircraft. The majority of the work carried out in this thesis required the design and development of the so-called GTEC 5G Simulator, which was used in conjunction with the GTEC Testbed to perform most of the measurement campaigns and performance evaluations by means of over-the-air transmissions

Cooperative Radio Communications for Green Smart Environments

The demand for mobile connectivity is continuously increasing, and by 2020 Mobile and Wireless Communications will serve not only very dense populations of mobile phones and nomadic computers, but also the expected multiplicity of devices and sensors located in machines, vehicles, health systems and city infrastructures. Future Mobile Networks are then faced with many new scenarios and use cases, which will load the networks with different data traffic patterns, in new or shared spectrum bands, creating new specific requirements. This book addresses both the techniques to model, analyse and optimise the radio links and transmission systems in such scenarios, together with the most advanced radio access, resource management and mobile networking technologies. This text summarises the work performed by more than 500 researchers from more than 120 institutions in Europe, America and Asia, from both academia and industries, within the framework of the COST IC1004 Action on "Cooperative Radio Communications for Green and Smart Environments". The book will have appeal to graduates and researchers in the Radio Communications area, and also to engineers working in the Wireless industry. Topics discussed in this book include: • Radio waves propagation phenomena in diverse urban, indoor, vehicular and body environments• Measurements, characterization, and modelling of radio channels beyond 4G networks• Key issues in Vehicle (V2X) communication• Wireless Body Area Networks, including specific Radio Channel Models for WBANs• Energy efficiency and resource management enhancements in Radio Access Networks• Definitions and models for the virtualised and cloud RAN architectures• Advances on feasible indoor localization and tracking techniques• Recent findings and innovations in antenna systems for communications• Physical Layer Network Coding for next generation wireless systems• Methods and techniques for MIMO Over the Air (OTA) testin