Analisi Sperimentale delle Prestazioni di Nodi Wireless LoRa in Presenza di Interferente

L’obiettivo dell’Internet of Things (IoT), come suggerisce il nome, è quello di connettere oggetti (spesso alimentati a batteria) alla rete Internet per poterne avere un controllo da remoto. Lo sviluppo di questa tecnologia prevede la progettazione di dispositivi che abbiano: un basso costo per unità, una durata della batteria sufficientemente lunga (anche dell’ordine di anni) quindi bassi consumi e la possibilità di realizzare un’ampia rete che possa supportare tante unità. Per questo elaborato è stata utilizzata la tecnologia LoRa, creata da Semtech. Essa lavora nelle frequenze ISM designate per le varie zone geografiche del mondo, presenta un Livello Fisico personalizzato ispirato alla modulazione CSS e un Livello MAC che si basa sul protocollo ALOHA puro. Lo scopo di questo elaborato è realizzare delle misure delle prestazioni in ambiente indoor tramite l’utilizzo di due nodi (End Devices) e un gateway. Sono state sviluppate due applicazioni Java per realizzare la comunicazione tra i dispositivi. Le misure sono state realizzate inizialmente con un nodo singolo, per osservarne il tasso di perdita di pacchetti (packet loss rate) e l’attenuazione di potenza sul canale (channel loss). Successivamente sono state inviate trasmissioni da entrambi i nodi, prima separatamente e poi in contemporanea, per valutare l’interferenza tra invii di messaggi con uguali impostazioni nello stesso canale. Per fare ciò è stato utilizzato un modello della comunicazione di canale che tiene conto del path loss e dello shadowing log-normale. I risultati hanno mostrato che con un solo nodo si tratta di una tecnologia affidabile. Per quanto riguarda i risultati delle misure con interferente è emersa una differenza con i valori attesi fino al 20%. Nell’elaborato vengono discussi i risultati ottenuti e possibili sviluppi futuri per questo tipo di sperimentazione.

Digital design of an EPC Gen2 controller for enhanced RFID tags

This thesis presents an improvement of the long range battery-less UHF RFID platform for sensor applications which is based on the open source Wireless Identification and Sensing Platform (WISP) project. The purpose of this work is to design a digital logic that performs the RFID EPC gen2 protocol communication, is able to acquire information by sensors and provide an accurate estimation of tag location ensuring low energy consumption. This thesis will describe the hardware architecture on which the digital logic was inserted, the Verilog code developed, the methods by which the digital logic was tested and an explorative study of chip synthesis on Cadence.

Precise Near-Field Focusing exploiting Bessel Beam Launchers for Wireless Power Transfer at millimeter waves

Wireless Power Transfer has become a promising technology to overcome the limits of wired solutions. Within this framework, the objective of this thesis is to study a WPT link at millimeter waves involving a particular type of antenna working in the radiative near-field, known as Bessel Beam (BB) Launcher. This antenna has been chosen for its peculiarity of generating a Bessel Beam which is by nature non-diffractive, showing good focusing and self-healing capabilities. In particular, a Bull-Eye Leaky Wave Antenna is designed and analysed, fed by a loop antenna and resonating at approximately 30 GHz. The structure excites a Hybrid-TE mode showing zeroth-order Bessel function over the z-component of the magnetic field. The same antenna is designed with two different dimensions, showing good wireless power transport properties. The link budgets obtained for different configurations are reported. With the aim of exploiting BB Launchers in wearable applications, a further analysis on the receiving part is conducted. For WPT wearable or implantable devices a reduced dimension of the receiver system must be considered. Therefore, an electrically large loop antenna in planar technology is modified, inserting phase shifters in order to increase the intensity of the magnetic field in its interrogation zone. This is fundamental when a BB Launcher is involved as transmitter. The loop antenna, in reception, shows a further miniaturization level since it is built such that its interrogation zone corresponds to the main beam dimension of transmitting BB Launcher. The link budget is evaluated with the new receiver showing comparable results with respect to previous configurations, showing an efficient WPT link for near-field focusing. Finally, a matching network and a full-wave rectifying circuit are attached to two of the different receiving systems considered. Further analysis will be carried out about the robustness of the square loop over biological tissues.

Efficient wireless coverage of in-building environments with low electromagnetic impact

The city of tomorrow is a major integrating stake, which crosses a set of major broad spectrum domains. One of these areas is the instrumentation of this city and the ubiquity of the exchange of data, which will give the pulse of this city (sensors) and its breathing in a hyper-connected world within indoor and outdoor dense areas (data exchange, 5G and 6G). Within this context, the proposed doctorate project has the objective to realize cost- and energy- effective, short-range communication systems for the capillary wireless coverage of in-door environments with low electromagnetic impact and for highly dense outdoor networks. The result will be reached through the combined use of: 1) Radio over Fiber (RoF) Technology, to bring the Radio Frequency (RF) signal to the different areas to be covered. 2) Beamforming antennas to send in real time the RF power just in the direction(s) where it is really necessary.

Wireless Network Analytics for Next Generation Spectrum Awareness

The importance of networks, in their broad sense, is rapidly and massively growing in modern-day society thanks to unprecedented communication capabilities offered by technology. In this context, the radio spectrum will be a primary resource to be preserved and not wasted. Therefore, the need for intelligent and automatic systems for in-depth spectrum analysis and monitoring will pave the way for a new set of opportunities and potential challenges. This thesis proposes a novel framework for automatic spectrum patrolling and the extraction of wireless network analytics. It aims to enhance the physical layer security of next generation wireless networks through the extraction and the analysis of dedicated analytical features. The framework consists of a spectrum sensing phase, carried out by a patrol composed of numerous radio-frequency (RF) sensing devices, followed by the extraction of a set of wireless network analytics. The methodology developed is blind, allowing spectrum sensing and analytics extraction of a network whose key features (i.e., number of nodes, physical layer signals, medium access protocol (MAC) and routing protocols) are unknown. Because of the wireless medium, over-the-air signals captured by the sensors are mixed; therefore, blind source separation (BSS) and measurement association are used to estimate the number of sources and separate the traffic patterns. After the separation, we put together a set of methodologies for extracting useful features of the wireless network, i.e., its logical topology, the application-level traffic patterns generated by the nodes, and their position. The whole framework is validated on an ad-hoc wireless network accounting for MAC protocol, packet collisions, nodes mobility, the spatial density of sensors, and channel impairments, such as path-loss, shadowing, and noise. The numerical results obtained by extensive and exhaustive simulations show that the proposed framework is consistent and can achieve the required performance.

Wireless Power Link Design for Both High-Power Inductive Coupling and Smart Metasurfaces Exploitation

As future technologies are going to be autonomous under the umbrella of the Internet of things (IoT) we can expect WPT to be the solution for intelligent devices. WPT has many industrial and medical applications both in the near-field and far-field domains. Considering the impact of WPT, this thesis is an attempt to design and realize both near-field and far-field WPT solutions for different application scenarios. A 27 MHz high frequency inductive wireless power link has been designed together with the Class-E switching inverter to compensate for the efficiency loss because of the varying weak coupling between transmitter and receiver because of their mutual misalignment. Then a system of three coils was introduced for SWIPT. The outer coil for WPT and the inner two coils were designed to fulfil the purpose of communication and testing, operating at frequencies different from the WPT coil. In addition to that, a trapping filter technique has also been adopted to ensure the EM isolation of the coils. Moreover, a split ring resonator-based dual polarization converter has been designed with good efficiency over a wide frequency range. The gap or cuts have been introduced in the adjacent sides of the square ring to make it a dual-polarization converter. The converter is also stable over a wide range of incident angles. Furthermore, a meta-element based intelligent surface has been designed to work in the reflection mode at 5 GHz. In this research activity, interdigital capacitors (IDCs) instead of ICs are introduced and a thin layer of the HfZrO between substrate and meta elements is placed whose response can be tuned and controlled with the applied voltage to achieve IRS.

Wireless solutions for the industrial internet of things

The fourth industrial revolution is paving the way for Industrial Internet of Things applications where industrial assets (e.g., robotic arms, valves, pistons) are equipped with a large number of wireless devices (i.e., microcontroller boards that embed sensors and actuators) to enable a plethora of new applications, such as analytics, diagnostics, monitoring, as well as supervisory, and safety control use-cases. Nevertheless, current wireless technologies, such as Wi-Fi, Bluetooth, and even private 5G networks, cannot fulfill all the requirements set up by the Industry 4.0 paradigm, thus opening up new 6G-oriented research trends, such as the use of THz frequencies. In light of the above, this thesis provides (i) a broad overview of the main use-cases, requirements, and key enabling wireless technologies foreseen by the fourth industrial revolution, and (ii) proposes innovative contributions, both theoretical and empirical, to enhance the performance of current and future wireless technologies at different levels of the protocol stack. In particular, at the physical layer, signal processing techniques are being exploited to analyze two multiplexing schemes, namely Affine Frequency Division Multiplexing and Orthogonal Chirp Division Multiplexing, which seem promising for high-frequency wireless communications. At the medium access layer, three protocols for intra-machine communications are proposed, where one is based on LoRa at 2.4 GHz and the others work in the THz band. Different scheduling algorithms for private industrial 5G networks are compared, and two main proposals are described, i.e., a decentralized scheme that leverages machine learning techniques to better address aperiodic traffic patterns, and a centralized contention-based design that serves a federated learning industrial application. Results are provided in terms of numerical evaluations, simulation results, and real-world experiments. Several improvements over the state-of-the-art were obtained, and the description of up-and-running testbeds demonstrates the feasibility of some of the theoretical concepts when considering a real industry plant.

Trajectory Planning in UAV-Aided Wireless Networks Via Reinforcement Learning

This thesis is focused on the design of a flexible, dynamic and innovative telecommunication's system for future 6G applications on vehicular communications. The system is based on the development of drones acting as mobile base stations in an urban scenario to cope with the increasing traffic demand and avoid network's congestion conditions. In particular, the exploitation of Reinforcement Learning algorithms is used to let the drone learn autonomously how to behave in a scenario full of obstacles with the goal of tracking and serve the maximum number of moving vehicles, by at the same time, minimizing the energy consumed to perform its tasks. This project is an extraordinary opportunity to open the doors to a new way of applying and develop telecommunications in an urban scenario by mixing it to the rising world of the Artificial Intelligence.

Unmanned Aerial Wireless Networks For The Internet of Things

The need for data collection from sensors dispersed in the environment is an increasingly important problem in the sector of telecommunications. LoRaWAN is one of the most popular protocols for low-power wide-area networks (LPWAN) that is made to solve the aforementioned problem. The aim of this study is to test the behavior of the LoRaWAN protocol when the gateway that collects data is implemented on a flying platform or, more specifically, a drone. This will be pursued using performance data in terms of access to the channel of the sensor nodes connected to the flying gateway. The trajectory of the aircraft is precomputed using a given algorithm and sensor nodes’ clusterization. The expected results are as follows: simulate the LoraWAN system behavior including the trajectory of the drone and the deployment of nodes; compare and discuss the effectiveness of the LoRaWAN simulator by conducting on-field trials, where the trajectory design and the nodes’ deployment are the same.

Sviluppo di un simulatore per comunicazioni wireless nella banda THz

L'oggetto di questo elaborato è lo studio di un collegamento wireless alle frequenze dei Terahertz, quindi nel range compreso tra i 300 GHz e i 3 THz. In particolare, si studierà il caso di una trasmissione wireless di alcuni metri all'interno di un ambiente chiuso, mostrando in che modo le diverse frequenze vengono attenuate. L’interesse per queste frequenze è motivato dalla quantità di tecnologie sviluppabili con esse, come ad esempio il 6G. Nell’elaborato verranno trattate anche le problematiche che si devono affrontare quando si sceglie di usare i THz, in particolare l’attenuazione dovuta all’assorbimento molecolare dovuto all’aria e alle condizioni atmosferiche variabili, il che rende la trasmissione THz ancora precaria.

Soluzioni per coperture wireless in ambiente indoor con l'ausilio di superfici intelligenti riconfigurabili

I sistemi di comunicazione 6G si prevede che soddisfino requisiti più stringenti rispetto alle reti 5G in termini di capacità di trasmissione, affidabilità, latenza, copertura, consumo energetico e densità di connessione. I miglioramenti che si possono ottenere agendo solo sugli end-points dell'ambiente wireless potrebbero non essere sufficienti per adempiere a tali obiettivi. Performance migliori potrebbero invece essere raggiunte liberandosi del postulato che fissa l'ambiente di propagazione come elemento incontrollabile. In questo panorama spicca una tecnologia recente che prende il nome di Reconfigurable Intelligent Surface (RIS) e che si pone l'obiettivo di rendere personalizzabile l'ambiente di propagazione wireless attraverso elaborazioni quasi passive di segnale. Una RIS è una superficie sottile ingegnerizzata al fine di possedere proprietà che le permettono di controllare dinamicamente le onde elettromagnetiche attraverso, ad esempio, la riflessione, rifrazione e focalizzazione del segnale. Questo può portare alla realizzazione del cosiddetto Smart Radio Environment (SRE), ovvero un ambiente di propagazione che non è visto come entità aleatoria incontrollabile, ma come parametro di design che svolge un ruolo fondamentale nel processo di ottimizzazione della rete. Nel presente elaborato, partendo da un modello macroscopico del comportamento di una RIS sviluppato dal gruppo di ricerca di propagazione e integrato all'interno di un simulatore di ray tracing, si effettua uno studio di coperture wireless con l'ausilio di RIS in semplici scenari indoor di riferimento.

A biosignal embedded system for physiological computing

Thesis submitted in the fulfilment of the requirements for the Degree of Master in Electronic and Telecomunications Engineering

Sistema sem fios para controlo de iluminação decorativa

Este projecto surgiu no contexto da solicitação de um dos clientes da empresa Castros Iluminações que pretendia um sistema de iluminação decorativa (baseada em LED) de dois conjuntos de 288 janelas, pertencendo cada conjunto a uma fachada diferente do edifício. Este sistema teria que prever a possibilidade de controlar a cor de cada janela individualmente, dando ao cliente a possibilidade de alterar o ambiente decorativo das fachadas do edifício. A utilização de comunicação sem fios foi justificada pela necessidade de evitar a quantidade enorme de cabos que seria necessário passar utilizando os sistemas comerciais convencionais e a impossibilidade de os esconder. Esta solução foi pensada para ser implementada num edifício com 14 Andares, facto que por si só inviabiliza a passajem de cabos. Para interligar todos os dispositivos de iluminação decorativa com um controlador portátil, e eliminar os problemas ligados à cablagem, foi utilizado o protocolo de comunicações sem fios ZigBee™. A escolha recaiu neste protocolo devido a factores como os seus baixos consumos, simplicidade do protocolo comparativamente com outras redes e o seu baixo custo. No desenvolvimento deste projecto foi utilizada a stack da Microchip©, versão gratuita, disponibilizada na internet e os seus transceivers de comunicação Zigbee™, MRF24j40MA. Para fazer a interface de comunicação com o utilizador, foi desenvolvida uma aplicação de Software para correr em computadores com ambiente Windows™. Esta aplicação foi desenvolvida em Visual Studio™ utilizando a linguagem C#. Foram efectuados alguns testes para se perceber a eficiência e robustez da comunicação ZigBee™ e apesar do número de dispositivos disponíveis para ensaios ser muito reduzido, foi possível verificar que, mesmo funcionando correctamente, o desempenho do sistema poderá ser melhorado, quer seja a nível da gestão das comunicações, quer a nível do software informático para controlo do ambiente decorativo das fachadas do edifício. O sistema, no actual estado de desenvolvimento, permite controlar a cor dos vários dispositivos da rede através do computador, com uma resolução de 24bits. A aplicação desenvolvida em Visual Studio™ permite controlar de forma simples e intuitiva para o utilizador, a cor do material iluminativo dos vários dispositivos da rede.

Consumer energy management system with integration of smart meters

This paper develops an energy management system with integration of smart meters for electricity consumers in a smart grid context. The integration of two types of smart meters (SM) are developed: (i) consumer owned SM and (ii) distributor owned SM. The consumer owned SM runs over a wireless platform - ZigBee protocol and the distributor owned SM uses the wired environment - ModBus protocol. The SM are connected to a SCADA system (Supervisory Control And Data Acquisition) that supervises a network of Programmable Logic Controllers (PLC). The SCADA system/PLC network integrates different types of information coming from several technologies present in modern buildings. The developed control strategy implements a hierarchical cascade controller where inner loops are performed by local PLCs, and the outer loop is managed by a centralized SCADA system, which interacts with the entire local PLC network. In order to implement advanced controllers, a communication channel was developed to allow the communication between the SCADA system and the MATLAB software. (C) 2014 The Authors. Published by Elsevier Ltd. This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/).

Formation Control Driven by Cooperative Object Tracking

In this paper we introduce a formation control loop that maximizes the performance of the cooperative perception of a tracked target by a team of mobile robots, while maintaining the team in formation, with a dynamically adjustable geometry which is a function of the quality of the target perception by the team. In the formation control loop, the controller module is a distributed non-linear model predictive controller and the estimator module fuses local estimates of the target state, obtained by a particle filter at each robot. The two modules and their integration are described in detail, including a real-time database associated to a wireless communication protocol that facilitates the exchange of state data while reducing collisions among team members. Simulation and real robot results for indoor and outdoor teams of different robots are presented. The results highlight how our method successfully enables a team of homogeneous robots to minimize the total uncertainty of the tracked target cooperative estimate while complying with performance criteria such as keeping a pre-set distance between the teammates and the target, avoiding collisions with teammates and/or surrounding obstacles.