A Multi-Frequency Investigation of Air-To-Ground Urban Propagation Using a GPU-based Ray Launching Algorithm

Unmanned Aerial Vehicles (UAV), also known as “drones”, are attracting increasing attention as enablers for many technical applications and services, and this trend is likely to continue in the next future. When compared to conventional terrestrial communications, those making use of UAVs as base- or relay-stations can definitely be more useful and flexible in reaction to specific events, like natural disasters and terrorist attacks. Among the many and different fields, UAV enabled communications emerge as one of the most promising solutions for next-generation mobile networks, with a special focus on the extension of coverage and capacity of mobile radio networks. Motivated by the air-to-ground (A2G) propagation conditions which are likely to be different than those experienced by traditional ground communication systems, this paper aims at investigating the narrowband properties of the air-to-ground channel for 5G communications and beyond by means of GPU accelerated ray launching simulations. Line of sight probability as well as path loss exponent and shadowing standard deviations are analysed for different UAV flight levels, frequencies and dense urban scenarios, and for different types of on board antennas. Thanks to the flexibility of the ray approach, the role played by the different electromagnetic interactions, namely reflection, diffraction and diffuse scattering, in the air-to-ground propagation process is also investigated. Computation time is reported as well to show that designing UAV communication networks and optimising their performances in a fast and reliable manner, might avoid exhausting – multiple - measurement campaigns

Investigation of Range Profiles from a Simplified Ship on Rough Sea Surface and Its Multipath Imaging Mechanisms

The range profiles of a two-dimension (2 D) perfect electric conductor (PEC) ship on a wind-driven rough sea surface are derived by performing an inverse discrete Fourier transform (IDFT) on the wide band backscattered field. The rough sea surface is assuming to be a PEC surface. The back scattered field is computed based on EM numerical simulation when the frequencies are sampled between 100 MHz and 700 MHz. Considering the strong coupling interactions between the ship and sea, the complicated multipath effect to the range profile characteristics is fully analyzed based on the multipath imaging mechanisms. The coupling mechanisms could be explained by means of ray theory prediction and numerical extraction of the coupling currents. The comparison of the range profile locations between ray theory prediction and surface current simulation is implemented and analyzed in this paper. Finally, the influence of different sea states on the radar target signatures has been examined and discussed

A Technical and Market study for WiMAX

Worldwide Interoperability for Microwave Access (WiMAX) is a broadband wireless technology based on IEEE 802.16-2004 and IEEE 802.16e-2005. This thesis is a study of WiMAX technology and market. The background of WiMAX development is introduced and opportunities and challenges for WiMAX are analyzed in the beginning. Then the thesis focuses on an overview of WiMAX technology, which addresses the physical layer, MAC layer and WiMAX network architecture. The deployment status is investigated in the fourth chapter. Both product development situation and market status are discussed in this section. In the last chapter, the future development trend of WiMAX is addressed

Probing the Interstellar Medium Toward Timing Array Millisecond Pulsars with the Murchison Widefield Array

Millisecond pulsars are highly sought-after targets for timing-array experiments that aim to detect ultra-low frequency gravitational waves. However, there are multiple challenges before this goal can be achieved. Interstellar medium effects on pulsar signals are amongst them. The magnitudes of these effects are much stronger at longer radio wavelengths, therefore low-frequency observations with the Murchison Widefield Array are especially promising for the related studies. This thesis presents such a study for two millisecond pulsars

Theoretical and experimental contributions for modeling wireless channels

Trabalho de Conclusão de Curso (graduação)—Universidade de Brasília, Faculdade de Tecnologia, Departamento de Engenharia Elétrica, 2017.Este trabalho de conclusão de curso visa agregar contribuições teóricas e experimentais para a modelagem de redes sem fio à partir de quatro projetos realizados durante um estágio supervisionado entre a Universidade de Brasília e a escola francesa de engenharia ENSEIRB-MATMECA durante o ano de 2017. Todos os projetos desse trabalho giram em torno do tema "desafios atuais nas comunicações sem fio" e tem como objetivo a apresentação de tais desafios através de uma breve introdução teórica seguida da realização de simulações, análises estatísticas ou medições em campo. O primeiro projeto propõem um estudo teórico e a validação experimental da distribuição de desvanecimento α-μ/Γ generalizada, usada nesse trabalho para caracterizar ambientes realistas que experimentam desvanecimento composto. Ainda no escopo de análises estatísticas, o segundo projeto propõe uma caracterização da qualidade do sinal celular à partir de dados de potência medidos usando um aplicativo Android de analise de qualidade de redes móveis. As análises estatísticas realizadas poderão auxiliar operadoras de telefonia móvel à parametrizar suas redes e contribuir para o melhoramento da cobertura celular no pais. Em seguida, o terceiro projeto desenvolvido nesse trabalho de conclusão de curso propõe estudos práticos e teóricos de interferência entre os sistema LTE 700MHz e TV digital em Brasília na região da Asa Norte, um tema recente de grande importância dada a desconexão da TV analógica no Brasil até 2018. Por fim, o quarto projeto, realizado em parceria com a Agência Nacional de Telecomunicações (ANATEL) propõe contribuições para o desenvolvimento de um simulador de rede IMT para uso em estudos de compartilhamento e compatibilidade proposto para ajudar na identificação de novas faixas de frequência para o IMT-2020. Os projetos propostos nesse trabalho focam na caracterização e modelagem de canais sem fio à partir do levantamento de estatísticas de primeira ordem, na análise de qualidade das redes celulares no país com base nas informações sobre a cobertura celular experimentada pelos usuários de telefonia móvel e na análise da interferência entre sistemas à partir de estudos entre o LTE e a TV digital e da busca de novas possíveis frequências para o 5G. A realização do estágio supervisionado e desse trabalho de conclusão de curso é um requerimento oficial para a obtenção do título de "Engenheiro diplomado do Instituto politécnico de Bordeaux, especialidade Engenharia eletrônica" pela ENSEIRB-MATMECA e para a obtenção do titulo de "Engenheiro de redes de comunicação" pela Universidade de Brasília.This final course assignment aims to add theoretical and experimental contributions to the modeling of wireless networks from four different projects carried out over an supervised internship held between the University of Brasília and the french school of engineering ENSEIRB-MATMECA during the year of 2017. All projects revolve around the central theme "current challenges in wireless communications" and aims to present such challenges through a brief theoretical introduction followed by simulations, statistical analyzes or field measurements. The first project proposes a theoretical study and the experimental investigation of the α-μ/Γ generalized fading distribution, used in this work to characterize realistic environments that experience composite fading. A second project, also based on statistical analysis, proposes a characterization of the mobile phone signal quality from power data measured using an Android application of mobile network quality analysis. Statistical analyzes can help mobile operators to parameterize their network and contribute to the improvement of cellular coverage in the country. Next, the third project developed in the internship proposes practical and theoretical studies of interference between the LTE 700MHz system and digital TV in Brasília in the region of Asa Norte, a recent topic of great importance given the analogue TV disconnection in Brazil until 2018. Finally, the fourth project, carried out in partnership with the National Telecommunications Agency (ANATEL), proposes contributions for the development of an IMT network simulator for use in sharing and compatibility studies to help in the identification of new frequency bands for the IMT-2020. The projects proposed in this work focus on the characterization and modeling of wireless channels from first order statistics, on the analysis of the quality of cellular networks in the country based on the information collected from the App about the network coverage experienced by final users and on the analysis of interference between systems based on studies between LTE and digital TV and on the search for new possible frequencies for 5G. The realization of the supervised internship was an official requirement to obtain the title of "Licensed Engineer of the Polytechnic Institute of Bordeaux, specialized in Electronic Engineering" by ENSEIRB-MATMECA and to obtain the title of "Network Communications Engineer" by the University of Brasília

Energy Efficient Small Cell Planning For High Capacity Wireless Networks

This thesis presents a new strategy to densify Small Cells (i.e., add more low powered base stations within macro networks) and enhance the coverage and capacity of Heterogeneous Networks. This is accomplished by designing Micro Cell for outdoor applications, Pico and Femtocell for indoor applications. It is shown that, there exists a free space propagation medium in all propagation environments due to Fresnel zones, and the path loss slope within this zone is similar to free space propagation medium. This forms the basis of our development of the present work. The salient feature of the proposed work has two main considerations (a) The cell radius of Small Cells must be within the first Fresnel zone break point, and (b) The minimum inter-cell distance must be greater than twice of Small Cell radius. The proposed network is simulated in real a radio network simulator called ATOLL. The simulation results showed that densify Small Cells not only enhanced the capacity and coverage of Heterogeneous Networks but also improved the carrier to interference ratio significantly. Since the proposed work allows UE (user equipment) to have Line of Sight (LOS) communication with the serving cell, and UE can have higher uplink (UL) signal to interference plus noise ratio (SINR) that will further allow UE to reduce its transmission power, which will consequently lead to a longer battery life for the UE and reduce the interference in the system

Accurate and efficient full-wave modelling for indoor radio wave propagation

The transition towards next-generation communication technologies has increased the need for accurate knowledge about the wireless channel. Knowledge of radio wave propagation is vital to the continued development of efficient wireless communications systems capable of providing a high data throughput and reliable connection. Thus, there is an increased need for accurate propagation models that can rapidly predict and describe the propagation channel. This is extremely challenging for indoor environments given the large variety of materials encountered and very complex and widely varying geometries.Currently, empirical or ray optical models are the most common for indoor propagation. Empirical models based on measurement campaigns provide limited accuracy, are very costly and time-consuming but provide rapid predictions. Deterministic models are applied to the geometrical representation of the environment and are based on Maxwell’s equations. They can produce more accurate predictions than empirical models. Ray tracing, an approximate model, is the most popular deterministic model for indoor propagation. The current trend of research is focused on improving its accuracy. Full-wave propagation models are based on the numerical solution of Maxwell’s equations. They are able to produce accurate predictions about the wireless channel. However, they are very computationally expensive. Thus, there has been limited attempts at developing indoor propagation models based on full-wave techniques. In this work, the Volume Electric Field Integral Equation (VEFIE) is used as the basis of a full-wave indoor propagation model. The 2D and 3D formulations of the VEFIE are applied to model the propagation of radio waves indoors. An enhancement to the 2D VEFIE, called 2D to 3D models, is developed to improve its accuracy and utilise its efficiency. It is primarily used for the prediction of time domain characteristics due to its high efficiency whereas the 3D VEFIE is shown to be suitable for frequency domain predictions

Design and Measurement-Based Evaluation of Multi-Antenna Mobile Terminals for LTE 3500 MHz Band

Design of multi-element antennas for small mobile terminals operating at higher frequencies remains challenging despite smaller antenna dimension and possibility of achieving electrically large separation between them. In this paper, the importance of the type of radiating elements operating at 3400-3600 MHz and their locations on the terminal chassis are highlighted. An isotropic radiation pattern that receives incoming signals from arbitrary directions is obtained by combining the radiation patterns of multiple antennas with localized chassis current distribution. Four multiport antennas configurations with two- and eight-element antennas are designed and evaluated experimentally in indoor propagation environments. Our proposed designs of multi-element antennas provide the highest MIMO channel capacity compared to their counterparts using antennas with less localized chassis current distribution, even in the presence of user's hand

Antennas and Propagation for UAV-Assisted Wireless Networks Towards Next Generation Mobile Systems

Unmanned Aerial Vehicles (UAV), also known as "drones", are attracting increasing attention as enablers for many technical applications and services, and this trend is likely to continue in the near future. UAVs are expected to be used extensively in civil and military applications where aerial surveillance and assistance in emergency situations are key factors. UAVs can be more useful and flexible in reaction to specific events, like natural disasters and terrorist attacks since they are faster to deploy, easier to reconfigure and assumed to have better communication means due to their improved position in the sky, improved visibility over ground, and reduced hindrance for propagation. In this regard, UAV enabled communications emerge as one of the most promising solutions for setting-up the next-generation mobile networks, with a special focus on the extension of coverage and capacity of mobile radio networks for 5G applications and beyond. However, air-to-ground (A2G) propagation conditions are likely to be different and more challenging than those experienced by traditional piloted aircraft. For this reason, knowledge of this specific propagation channel – together with the UAV antenna design and placement - is paramount for defining an efficient communication system and for evaluating its performance. This PhD thesis tackles this challenge, and it aims at further investigating the narrowband properties of the air-to-ground propagation channel by means of GPU accelerated ray launching simulations for 5G communications and beyond. As a conclusion, this PhD thesis might bring deep insights into the air-to-ground channel characteristics and UAV antenna design, which can be helpful for designing UAV communication networks and evaluating or optimising their performances in a fast and reliable manner, with no need for exhausting – multiple - in-field measurement campaigns

Modelling of radio wave propagation using Finite Element Analysis.

Fourth generation (4G) wireless communication systems are intended to support high data rates which requires careful and accurate modelling of the radio environment. In this thesis, for the first time finite clement based accurate and computationally efficient models of wave propagation in different outdoor and indoor environments has been developed. Three different environments were considered: the troposphere, vegetation and tunnels and wave propagation in these environments were modelled using finite element analysis. Use of finite elements in wave propagation modelling is a novel idea although many propagation models and approaches were used in past. Coverage diagrams, path loss contours and power levels were calculated using developed models in the troposphere, vegetation and tunnels. Results obtained were compared with commercially available software Advanced Refractive Effects Prediction Software (AREPS) to validate the accuracy of the developed approach and it is shown that results were accurate with an accuracy of 3dB. The developed models were very flexible in handling complex geometries and similar analysis can be easily extended to other environments. A fully vectored finite element base propagation model was developed for straight and curved tunnels. An optimum range of values of different electrical parameters for tunnels of different shapes has been derived. The thesis delivered a novel approach to modelling radio channels that provided a fast and accurate solution of radio wave propagation in realistic environments. The results of this thesis will have a great impact in modelling and characterisation of future wireless communication systems