Design, implementation and testing of a real-time mobile WiMAX testbed featuring MIMO technology

Postprint (author’s final draft

A real-time FPGA-based implementation of a high-performance MIMO-OFDM mobile WiMAX transmitter

The Multiple Input Multiple Output (MIMO)-Orthogonal Frequency Division Multiplexing (OFDM) is considered a key technology in modern wireless-access communication systems. The IEEE 802.16e standard, also denoted as mobile WiMAX, utilizes the MIMO-OFDM technology and it was one of the first initiatives towards the roadmap of fourth generation systems. This paper presents the PHY-layer design, implementation and validation of a high-performance real-time 2x2 MIMO mobile WiMAX transmitter that accounts for low-level deployment issues and signal impairments. The focus is mainly laid on the impact of the selected high bandwidth, which scales the implementation complexity of the baseband signal processing algorithms. The latter also requires an advanced pipelined memory architecture to timely address the datapath operations that involve high memory utilization. We present in this paper a first evaluation of the extracted results that demonstrate the performance of the system using a 2x2 MIMO channel emulation.Postprint (published version

MATLAB as a Design and Verification Tool for the Hardware Prototyping of Wireless Communication Systems

Peer ReviewedPostprint (published version

WING/WORLD: An Open Experimental Toolkit for the Design and Deployment of IEEE 802.11-Based Wireless Mesh Networks Testbeds

Wireless Mesh Networks represent an interesting instance of light-infrastructure wireless networks. Due to their flexibility and resiliency to network failures, wireless mesh networks are particularly suitable for incremental and rapid deployments of wireless access networks in both metropolitan and rural areas. This paper illustrates the design and development of an open toolkit aimed at supporting the design of different solutions for wireless mesh networking by enabling real evaluation, validation, and demonstration. The resulting testbed is based on off-the-shelf hardware components and open-source software and is focused on IEEE 802.11 commodity devices. The software toolkit is based on an "open" philosophy and aims at providing the scientific community with a tool for effective and reproducible performance analysis of WMNs. The paper describes the architecture of the toolkit, and its core functionalities, as well as its potential evolutions

Building the Future Internet through FIRE

The Internet as we know it today is the result of a continuous activity for improving network communications, end user services, computational processes and also information technology infrastructures. The Internet has become a critical infrastructure for the human-being by offering complex networking services and end-user applications that all together have transformed all aspects, mainly economical, of our lives. Recently, with the advent of new paradigms and the progress in wireless technology, sensor networks and information systems and also the inexorable shift towards everything connected paradigm, first as known as the Internet of Things and lately envisioning into the Internet of Everything, a data-driven society has been created. In a data-driven society, productivity, knowledge, and experience are dependent on increasingly open, dynamic, interdependent and complex Internet services. The challenge for the Internet of the Future design is to build robust enabling technologies, implement and deploy adaptive systems, to create business opportunities considering increasing uncertainties and emergent systemic behaviors where humans and machines seamlessly cooperate

Building the Future Internet through FIRE

The Internet as we know it today is the result of a continuous activity for improving network communications, end user services, computational processes and also information technology infrastructures. The Internet has become a critical infrastructure for the human-being by offering complex networking services and end-user applications that all together have transformed all aspects, mainly economical, of our lives. Recently, with the advent of new paradigms and the progress in wireless technology, sensor networks and information systems and also the inexorable shift towards everything connected paradigm, first as known as the Internet of Things and lately envisioning into the Internet of Everything, a data-driven society has been created. In a data-driven society, productivity, knowledge, and experience are dependent on increasingly open, dynamic, interdependent and complex Internet services. The challenge for the Internet of the Future design is to build robust enabling technologies, implement and deploy adaptive systems, to create business opportunities considering increasing uncertainties and emergent systemic behaviors where humans and machines seamlessly cooperate

System design and validation of multi-band OFDM wireless communications with multiple antennas

[no abstract

A Study of 5G Cellular Connectivity to Unmanned Aerial Vehicles

The market of unmanned aerial vehicles (UAVs) has seen significant growth in the past ten years on both the commercial and military sides. The applications for UAVs are endless and options by manufacturers allow users to modify their drones for their specific goals. This industry has opened up the excitement of piloting vehicles in the air, photography, videography, exploration of nature from a different point of view and many other hobbies assisted by the emergence of UAVs. The growth of this industry coincides with the roll out of new 5G cellular network technology. This upgrade in cellular network infrastructure allows users higher bandwidth, lower latency, more devices per cell and higher reliability. This has created the question, is 5G suited to support UAV activity? Potentially allowing for two-way transmission of images, videos and data between ground users and the unmanned aerial vehicle. There are many challenges that are presented in flying under these communication conditions which need to be explored such as signal reliability, especially in rural areas, the effects of rapidly changing altitudes or velocity of the drone and the effects of antennas that are tuned for terrestrial users. The first of its kind work provided in this thesis, will show results for different UAV experiments on a commercial 5G cellular network in the Clemson, South Carolina area. This is a comprehensive study of both low-band and mid-band 5G cellular coverage relating to UAVs as well as a baseline to existing LTE coverage when available. Featuring first of its kind permission to conduct research on a fully commercial cellular network. This research area is largely new, limited information is currently public on the research into commercial 5G cellular networks supporting UAVs. Other researchers are also starting to collect different key performance indicators (KPIs) for flight signals. Most of their works differ in setup, often using private base stations to give connection, but many of these works will be discussed further in the thesis. LTE and 5G enabled flight allows for a wide variety of applications to use UAVs such as natural disaster assessment, animal poaching surveillance, wild fire detection and prevention, assessing the scene of an accident before police arrive and other more hobby or recreational uses. The end goal is to assure that 5G connection is strong enough to transmit the UAVs real time data, which necessary to help first responders on the ground. When many of the potential uses of a cellular connected UAV are potentially life saving, every second counts and signal needs to be fast, reliable and low latency. Therefore, reliable and high bandwidth communication is necessary for unmanned aerial vehicles to take the next step in real life use cases and to begin to explore the option of beyond visual line of sight (BVLoS) flight and 5G might be the network tools which can get it there