WiMAX spectrum virtualization and network federation

Ogunleye, Babatunde Samuel

January 2017

Spectrum management in wireless broadband networks as regards its cost and its efficient usage has posed a huge challenge for mobile network operators. Traditionally, network operators had exclusive rights to access the band of spectrum allocated to them, but with the high price of spectrum license, it is becoming necessary to find alternative ways to use and access spectrum more efficiently. Resource virtualization is a method which has been extensively adopted in hardware computing for creating abstract versions of physical hardware resources and it has proven to be a powerful technique for customized resource provision and sharing. This idea of resource virtualization is gradually being transferred into the domain of wireless mobile network resource management but the ideas around it are still evolving. Since spectrum is an important wireless network resource, it is imperative to provide an efficient and cost effective means for the resource to be accessed and utilized. Therefore the idea of spectrum virtualization is investigated in this research as a possible solution to this problem. To expand on the notion of spectrum virtualization, this research further explores the idea of network federation. Network Federation involves the interconnection of diverse network components to be operated as a single seamless network. This will enable them share their network resources while the networks are geographically dispersed and managed by different network operators. To fully implement these concepts there is a need for a well-developed network framework. This research proposes two novel architectures for spectrum virtualization and network federation using the WiMAX (Worldwide Interoperability for Microwave Exchange) wireless broadband technology. The proposed WiMAX spectrum virtualization architecture introduces a novel entity known as the Virtual Spectrum Hypervisor (VS-Hypervisor). This VS-Hypervisor bears the responsibility of spectrum management and virtualization within the WiMAX framework. In the implementation of WiMAX network federation, the novel architecture enables the cooperative existence of multiple WiMAX base-stations having virtualization capabilities with overlapping cellular coverage areas for the purpose of sharing their spectrum resources. In this architecture, a novel federation control plane known as the Virtual Spectrum Exchange Locale (VSEL) is proposed. The VSEL facilitates the VS-Hypervisors in the federated physical base-stations to be able to negotiate and exchange spectrum between themselves to match their spectrum needs. The architectures for WiMAX spectrum virtualization and network federation was modelled and implemented using the OPNET Modeler. Results obtained validated their efficacy with respect to the effective management of the wireless network spectrum. Therefore this proposed network architectures would help network operators optimize their radio networks.

Electrical Engineering

Broadband Networks

Communications Research

Infrastructure sharing of 5G mobile core networks on an SDN/NFV platform

Mwangama, Joyce Bertha

January 2017

When looking towards the deployment of 5G network architectures, mobile network operators will continue to face many challenges. The number of customers is approaching maximum market penetration, the number of devices per customer is increasing, and the number of non-human operated devices estimated to approach towards the tens of billions, network operators have a formidable task ahead of them. The proliferation of cloud computing techniques has created a multitude of applications for network services deployments, and at the forefront is the adoption of Software-Defined Networking (SDN) and Network Functions Virtualisation (NFV). Mobile network operators (MNO) have the opportunity to leverage these technologies so that they can enable the delivery of traditional networking functionality in cloud environments. The benefit of this is reductions seen in the capital and operational expenditures of network infrastructure. When going for NFV, how a Virtualised Network Function (VNF) is designed, implemented, and placed over physical infrastructure can play a vital role on the performance metrics achieved by the network function. Not paying careful attention to this aspect could lead to the drastically reduced performance of network functions thus defeating the purpose of going for virtualisation solutions. The success of mobile network operators in the 5G arena will depend heavily on their ability to shift from their old operational models and embrace new technologies, design principles and innovation in both the business and technical aspects of the environment. The primary goal of this thesis is to design, implement and evaluate the viability of data centre and cloud network infrastructure sharing use case. More specifically, the core question addressed by this thesis is how virtualisation of network functions in a shared infrastructure environment can be achieved without adverse performance degradation. 5G should be operational with high penetration beyond the year 2020 with data traffic rates increasing exponentially and the number of connected devices expected to surpass tens of billions. Requirements for 5G mobile networks include higher flexibility, scalability, cost effectiveness and energy efficiency. Towards these goals, Software Defined Networking (SDN) and Network Functions Virtualisation have been adopted in recent proposals for future mobile networks architectures because they are considered critical technologies for 5G. A Shared Infrastructure Management Framework was designed and implemented for this purpose. This framework was further enhanced for performance optimisation of network functions and underlying physical infrastructure. The objective achieved was the identification of requirements for the design and development of an experimental testbed for future 5G mobile networks. This testbed deploys high performance virtualised network functions (VNFs) while catering for the infrastructure sharing use case of multiple network operators. The management and orchestration of the VNFs allow for automation, scalability, fault recovery, and security to be evaluated. The testbed developed is readily re-creatable and based on open-source software.

Electrical Engineering

Broadband Networks

Communications Research

Hybrid Broadband Ground-Motion Simulation Using Scenario Earthquakes for the Istanbul Area

Reshi, Owais A.

13 April 2016

Seismic design, analysis and retrofitting of structures demand an intensive assessment of potential ground motions in seismically active regions. Peak ground motions and frequency content of seismic excitations effectively influence the behavior of structures. In regions of sparse ground motion records, ground-motion simulations provide the synthetic seismic records, which not only provide insight into the mechanisms of earthquakes but also help in improving some aspects of earthquake engineering. Broadband ground-motion simulation methods typically utilize physics-based modeling of source and path effects at low frequencies coupled with high frequency semi-stochastic methods. I apply the hybrid simulation method by Mai et al. (2010) to model several scenario earthquakes in the Marmara Sea, an area of high seismic hazard. Simulated ground motions were generated at 75 stations using systematically calibrated model parameters. The region-specific source, path and site model parameters were calibrated by simulating a Mw4.1 Marmara Sea earthquake that occurred on November 16, 2015 on the fault segment in the vicinity of Istanbul. The calibrated parameters were then used to simulate the scenario earthquakes with magnitudes Mw6.0, Mw6.25, Mw6.5 and Mw6.75 over the Marmara Sea fault. Effects of fault geometry, hypocenter location, slip distribution and rupture propagation were thoroughly studied to understand variability in ground motions. A rigorous analysis of waveforms reveal that these parameters are critical for determining the behavior of ground motions especially in the near-field. Comparison of simulated ground motion intensities with ground-motion prediction quations indicates the need of development of the region-specific ground-motion prediction equation for Istanbul area. Peak ground motion maps are presented to illustrate the shaking in the Istanbul area due to the scenario earthquakes. The southern part of Istanbul including Princes Islands show high amplitudes of shaking. The study serves as a step towards dynamic risk quantification for the Istanbul area that integrates physics based ground-motion simulations into an innovative dynamic exposure model to quantify risk.

Earthquakes

Hybrid Broadband

Simulation

Istanbul

Scenario Earthquakes

Fixed-to-mobile broadband substitution in South Africa.

Moroeng, Letlhogonolo Hendrick.

17 October 2012

Broadband is an important technology for development. Research has proven that development is directly linked to high speed internet. Over the past few years mobile broadband has overtaken fixed-line broadband as a primary connection for many households. The purpose of this exploratory study was to investigate how pricing and quality of service have either encouraged or inhibited fixed-to-mobile broadband in South Africa, and research if there are any other factors affecting broadband growth. The study, conducted in a predominantly middle-income neighbourhood, found that there is a trend towards fixed-to-mobile broadband substitution in South Africa.

Broadband

Mobile communication systems

South Africa

Barriers to broadband market development in rural areas in South Africa.

Macharia, Caroline Wangari

25 July 2013

Thesis (M.M. (ICT Policy and Regulation))--University of the Witwatersrand, Faculty of Commerce, Law and Management, Graduate School of Public and Development, 2013. / This research study investigates challenges affecting the supply and demand side factors of the broadband ecosystem that hinder the market development of broadband in rural areas in South Africa and how policy and regulation has affected the evolution of the broadband ecosystem in rural areas. Although the elements of the broadband ecosystem are strong and well placed in urban areas, not all elements of the broadband ecosystem in rural areas are in place and equally strong. The relative strengths and weaknesses of the different elements of the broadband ecosystem in rural areas are unknown and demand and supply side factors are not understood. Hence the broadband policy may not be based on a full understanding of the complex ecosystem. The study points to a classic case of market failure that exists in rural areas in relation to the broadband market development. The study identifies that a governance framework, investment management framework, universal access funding model, sufficient frequency spectrum resources, policies and regulation that specifically address the development of the broadband market in rural areas are lacking. Although the barriers and gaps identified in this study are known to the industry this research study goes further to corroborate from an academic research perspective the existence of these barriers that are affecting the broadband market development of rural areas.

Broadband

Rural areas

South Africa

Market development

IMPACT OF BROADBAND ON RESEARCH, INNOVATION AND EMPLOYMENT

JOSHI, YAGHA RAJ

01 June 2021

I begin chapter I with an examination of the effect of broadband on quantitative and qualitative aspects of research. This paper investigates whether access to the Internet is positively correlated with journal articles. I employ data sets from the world bank for 190 countries from 2000 to 2018 and run two types of regressions: Poisson and Negative Binomial. Our results indicate that broadband facilitates to write more journal articles and get more citations. My second chapter concerns access to broadband, fixed telephone, and mobile cellular is expected to have a positive impact on innovations. This paper investigates whether or not access to the Internet and telephone is positively correlated with innovation. We employ data sets from the world bank for 190 countries from 2000 to 2018 and run two types of regressions: OLS and fixed effect. Within each method, we examine how the income-level of the countries affects the answer. Our results indicate that broadband, telephone, and mobile cellular facilitates innovation. We explore two possible explanations for this: i) there are increasing marginal benefits of broadband deployment, ii) broadband creates a positive externality that indirectly enhances innovation. The conclusion is robust to various income level countries. In the third chapter, I examine how a connection to the internet and telephone affect labor market outcomes. We employ datasets from the world bank for 190 countries from 2000 to 2018 and employ three types of regressions: OLS, fixed effect estimator, and non-linear model. Within each method, we examine how the income status, gender, education level affects the answer.

Broadband

Employment

Innovation

Patent

Research

Trademark

Study of nonlinear transmission lines and their applications

Payandehjoo, Kasra.

January 2006

No description available.

Telecommunication lines.

A Comparison Between Synchronous CDMA and Orthogonal Frequency Division Multiplexing (OFDM) for Fixed Broadband Wireless Access

Chheda, Shital Ratilal

25 April 2002

The growth of broadband Internet access has paved the way for the development of many new technologies. As the cost of implementing broadband access soars, the best alternative will be to use fixed wireless for these services. This thesis addresses the possibility of 3rd Generation (3G) mobile cellular wireless systems as the basis for fixed broadband wireless service. Two of the 3G technologies aimed at providing fixed broadband wireless access are Time Division Synchronous Code Division Multiple Access (TD-SCDMA) and Orthogonal Frequency Division Multiplexing (OFDM). This thesis aims to provide a preliminary study on using TD-SCDMA and OFDM for broadband wireless systems. Currently, there is not enough theory and information to establish the feasibility of using either of these technologies for broadband wireless access. First, the basic features and background on synchronous CDMA and OFDM are presented for the reader to better understand these technologies. Then, an example TD-SCDMA system is described, and some analytical and experimental results are presented. Finally, TD-SCDMA's technologies, along with this system's attributes, are compared analytically to that of Vector OFDM (VOFDM). / Master of Science

OFDM

SCDMA

VOFDM

broadband

wireless

synchronous

A general broadband matching theory and its application

Tsai, Cheng-Kwang

January 1981

No description available.

communication systems

reflection coefficient

equalizer

general broadband

High Performance Broadband Photodetectors Based on Graphene/Semiconductor Heterostructures

Wang, Yifei

15 April 2022

Graphene, a monolayer of carbon atoms, has gained prominence to augment existing chip-scale photonic and optoelectronic applications, especially for sensing in optical radiation, owing to its distinctive electrical properties and bandgap as well as its atomically thin profile. As a building block of photodetection, graphene has been co-integrated with mature silicon technology to realize the on-chip, high-performance photo-detecting platforms with broad spectral response from the deep-ultraviolet (UV) to the mid-infrared (MIR) regime. The recent state-of-the-art graphene-based photodetectors utilizing the combination of colloidal quantum dots (QDs) and graphene have been intensively studied, where QDs function as the absorber and the role of graphene is as a fast carrier recirculating channel. With such a configuration, an ultrahigh sensitivity can be achieved on account of the photogating mechanism; however, the response time is slow and limited to the millisecond-to-second range. To achieve balance between high sensitivity and fast response time, we have demonstrated a new photodetector that is based on graphene/two-dimensional heterostructures. The homogeneous thickness and the large contact of the heterostructure give rise to fast carrier transporting between the thin absorber layer and the graphene, leading to a fast response time. This thesis carefully investigates the optimization of fabrication as well as optoelectronic characterization of photodetectors based on graphene/semiconductor heterostructures field-effect transistors (GFETs). GFETs with different architectures were demonstrated and systematically studied under optical illumination ranging from deep-UV to MIR at varying optical powers. Noise behaviors have been studied under different device parameters such as device structure, area and gate-bias. Results show that the flicker noise of graphene-based devices can be explained by the McWhorter model in which the fluctuation of carrier numbers is the dominant process of noise in low frequencies; thus, it can be scaled down by reducing the number of introduced charged carriers with optimized fabrication. Besides, the impact of absorber on top of graphene and the bottom substrate has been comprehensively explored through various experimental techniques including current-voltage (IV), photo-response dynamics, and noise characterization measurements. With our configuration, the high sensitivity and fast response time of photodetectors can be obtained at the same time. In addition to this, the study of the bottom substrate with different doping levels suggests a concept of dual-photogating effect which is induced by the top absorbent material and the photoionization of the doped silicon substrate. In summary, this thesis showcases novel device architecture and fabrication procedures of GFETs photodetectors, optimizes device structure, quantifies the performance and evaluates the effect of various absorbent materials and substrate. It provides insight into the improvement of possible routes to achieve a broadband photo-detecting system with higher sensitivity, faster response time and lower noise level. / Doctor of Philosophy / The rapid expansion of networked devices and the development of the Internet of Things have given rise to an internet traffic and data explosion. Since conventional electrical interconnects are unable to rise to the occasion of the ever-growing demands of information technology and communication networking, next-generation alternative interconnects with higher performance and lower loss are attractive alternatives as the chip-scale optical interconnection. Among various optical interconnects, photodetectors play significant roles by converting optical input into electrical signal output. Sensing of light has a great impact in daily applications such as telecommunications, night vision, biomedical imaging and biochemical sensing. Graphene, belonging to the class of 2-dimensional materials, shows enormous potential as a building block of photodetection owing to its outstanding optical and electrical properties. One possible route to develop a sensitive and fast-operating on-chip photodetector is to integrate graphene into silicon photonics platforms since the latter has been widely studied and driven to maturity. In this thesis, graphene-based photodetectors with novel architectures have been fabricated, demonstrated and systematically investigated. Various measurements have been taken to quantify the performance of photodetectors in a wide detecting range from deep ultraviolet to mid-infrared.

Photodetector

Broadband

Ultra-fast

Graphene FETs

Heterostructures