Surveillance risks in IoT applied to smart cities

Nowadays, cities deal with unprecedented pollution and overpopulation problems, and Internet of Things (IoT) technologies are supporting them in facing these issues and becoming increasingly smart. IoT sensors embedded in public infrastructure can provide granular data on the urban environment, and help public authorities to make their cities more sustainable and efficient. Nonetheless, this pervasive data collection also raises high surveillance risks, jeopardizing privacy and data protection rights. Against this backdrop, this thesis addresses how IoT surveillance technologies can be implemented in a legally compliant and ethically acceptable fashion in smart cities. An interdisciplinary approach is embraced to investigate this question, combining doctrinal legal research (on privacy, data protection, criminal procedure) with insights from philosophy, governance, and urban studies. The fundamental normative argument of this work is that surveillance constitutes a necessary feature of modern information societies. Nonetheless, as the complexity of surveillance phenomena increases, there emerges a need to develop more fine-attuned proportionality assessments to ensure a legitimate implementation of monitoring technologies. This research tackles this gap from different perspectives, analyzing the EU data protection legislation and the United States and European case law on privacy expectations and surveillance. Specifically, a coherent multi-factor test assessing privacy expectations in public IoT environments and a surveillance taxonomy are proposed to inform proportionality assessments of surveillance initiatives in smart cities. These insights are also applied to four use cases: facial recognition technologies, drones, environmental policing, and smart nudging. Lastly, the investigation examines competing data governance models in the digital domain and the smart city, reviewing the EU upcoming data governance framework. It is argued that, despite the stated policy goals, the balance of interests may often favor corporate strategies in data sharing, to the detriment of common good uses of data in the urban context.

Hybrid ground-aerial mesh networks for IoT monitoring applications: network design and software platform development

The Internet of Things (IoT) has grown rapidly in recent years, leading to an increased need for efficient and secure communication between connected devices. Wireless Sensor Networks (WSNs) are composed of small, low-power devices that are capable of sensing and exchanging data, and are often used in IoT applications. In addition, Mesh WSNs involve intermediate nodes forwarding data to ensure more robust communication. The integration of Unmanned Aerial Vehicles (UAVs) in Mesh WSNs has emerged as a promising solution for increasing the effectiveness of data collection, as UAVs can act as mobile relays, providing extended communication range and reducing energy consumption. However, the integration of UAVs and Mesh WSNs still poses new challenges, such as the design of efficient control and communication strategies. This thesis explores the networking capabilities of WSNs and investigates how the integration of UAVs can enhance their performance. The research focuses on three main objectives: (1) Ground Wireless Mesh Sensor Networks, (2) Aerial Wireless Mesh Sensor Networks, and (3) Ground/Aerial WMSN integration. For the first objective, we investigate the use of the Bluetooth Mesh standard for IoT monitoring in different environments. The second objective focuses on deploying aerial nodes to maximize data collection effectiveness and QoS of UAV-to-UAV links while maintaining the aerial mesh connectivity. The third objective investigates hybrid WMSN scenarios with air-to-ground communication links. One of the main contribution of the thesis consists in the design and implementation of a software framework called "Uhura", which enables the creation of Hybrid Wireless Mesh Sensor Networks and abstracts and handles multiple M2M communication stacks on both ground and aerial links. The operations of Uhura have been validated through simulations and small-scale testbeds involving ground and aerial devices.

Proximity detection protocols for IoT devices

In recent years, we have witnessed the growth of the Internet of Things paradigm, with its increased pervasiveness in our everyday lives. The possible applications are diverse: from a smartwatch able to measure heartbeat and communicate it to the cloud, to the device that triggers an event when we approach an exhibit in a museum. Present in many of these applications is the Proximity Detection task: for instance the heartbeat could be measured only when the wearer is near to a well defined location for medical purposes or the touristic attraction must be triggered only if someone is very close to it. Indeed, the ability of an IoT device to sense the presence of other devices nearby and calculate the distance to them can be considered the cornerstone of various applications, motivating research on this fundamental topic. The energy constraints of the IoT devices are often in contrast with the needs of continuous operations to sense the environment and to achieve high accurate distance measurements from the neighbors, thus making the design of Proximity Detection protocols a challenging task.

NB-IoT via non terrestrial networks

Massive Internet of Things is expected to play a crucial role in Beyond 5G (B5G) wireless communication systems, offering seamless connectivity among heterogeneous devices without human intervention. However, the exponential proliferation of smart devices and IoT networks, relying solely on terrestrial networks, may not fully meet the demanding IoT requirements in terms of bandwidth and connectivity, especially in areas where terrestrial infrastructures are not economically viable. To unleash the full potential of 5G and B5G networks and enable seamless connectivity everywhere, the 3GPP envisions the integration of Non-Terrestrial Networks (NTNs) into the terrestrial ones starting from Release 17. However, this integration process requires modifications to the 5G standard to ensure reliable communications despite typical satellite channel impairments. In this framework, this thesis aims at proposing techniques at the Physical and Medium Access Control layers that require minimal adaptations in the current NB-IoT standard via NTN. Thus, firstly the satellite impairments are evaluated and, then, a detailed link budget analysis is provided. Following, analyses at the link and the system levels are conducted. In the former case, a novel algorithm leveraging time-frequency analysis is proposed to detect orthogonal preambles and estimate the signals’ arrival time. Besides, the effects of collisions on the detection probability and Bit Error Rate are investigated and Non-Orthogonal Multiple Access approaches are proposed in the random access and data phases. The system analysis evaluates the performance of random access in case of congestion. Various access parameters are tested in different satellite scenarios, and the performance is measured in terms of access probability and time required to complete the procedure. Finally, a heuristic algorithm is proposed to jointly design the access and data phases, determining the number of satellite passages, the Random Access Periodicity, and the number of uplink repetitions that maximize the system's spectral efficiency.

Satellite IoT: a Study and Performance Analysis of GEO and LEO Systems

The study is divided into two main part: one focused on the GEO Satellite IoT and the other on the LEO Satellite IoT. Concerning the GEO Satellite IoT, the activity has been developed in the context of EUMETSAT Data Collection Service (DCS) by investigating the performance at the receiver within challenging scenarios. DCS are provided by several GEO Satellite operators, giving almost total coverage around the world. In this study firstly an overview of the DCS end-to-end architecture is given followed by a detailed description of both the tools used for the simulations: the DCP-TST (message generator and transmitter) and the DCP-RX (receiver). After generating several test messages, the performances have been evaluated with the addition of impairments (CW and sweeping interferences) and considerations in terms of BER and Good Messages are produced. Furthermore, a study on the PLL System is also conducted together with evaluations on the effectiveness of tuning the PLL Bw on the overall performance. Concerning the LEO Satellite IoT, the activity was carried out in the framework of the ASI Bidirectional IoT Satellite Service (BISS) Project. The elaborate covers a survey about the possible services that the project can accomplish and a technical analysis on the uplink MA. In particular, the LR-FHSS is proved to be a valid alternative for the uplink through an extensive analysis on its Network capacity and through the study of an analytic model for Success Probability with its Matlab implementation.

Implementazione di un protocollo Header-compression a livello applicazione per scenari IoT

Il fenomeno noto come Internet of Things costituisce oggi il motore principale dell'espansione della rete Internet globale, essendo artefice del collegamento di miliardi di nuovi dispositivi. A causa delle limitate capacità energetiche e di elaborazione di questi dispositivi è necessario riprogettare molti dei protocolli Internet standard. Un esempio lampante è costituito dalla definizione del Constrained Application Protocol (CoAP), protocollo di comunicazione client-server pensato per sostituire HTTP in reti IoT. Per consentire la compatibilità tra reti IoT e rete Internet sono state definite delle linee guida per la mappatura di messaggi CoAP in messaggi HTTP e viceversa, consentendo così l'implementazione di proxies in grado di connettere una rete IoT ad Internet. Tuttavia, questa mappatura è circoscritta ai soli campi e messaggi che permettono di implementare un'architettura REST, rendendo dunque impossibile l'uso di protocolli di livello applicazione basati su HTTP.La soluzione proposta consiste nella definizione di un protocollo di compressione adattiva dei messaggi HTTP, in modo che soluzioni valide fuori dagli scenari IoT, come ad esempio scambio di messaggi generici, possano essere implementate anche in reti IoT. I risultati ottenuti mostrano inoltre che nello scenario di riferimento la compressione adattiva di messaggi HTTP raggiunge prestazioni inferiori rispetto ad altri algoritmi di compressione di intestazioni (in particolare HPACK), ma più che valide perchè le uniche applicabili attualmente in scenari IoT.

A novel approach to Non-Orthogonal Random Access with application to NB-IoT NTN systems

In the Massive IoT vision, millions of devices need to be connected to the Internet through a wireless access technology. However, current IoT-focused standards are not fully prepared for this future. In this thesis, a novel approach to Non-Orthogonal techniques for Random Access, which is the main bottleneck in high density systems, is proposed. First, the most popular wireless access standards are presented, with a focus on Narrowband-IoT. Then, the Random Access procedure as implemented in NB-IoT is analyzed. The Non-Orthogonal Random Access technique is presented next, along with two potential algorithms for the detection of non-orthogonal preambles. Finally, the performance of the proposed solutions are obtained through numerical simulations.

Analisi e simulazione di protocolli di accesso multiplo per reti IoT 6G cell-free

Lo scopo delle reti mobili è fornire ai dispositivi wireless accesso a una grande varietà di servizi dati, in un’ampia area geografica. Nonostante le reti cellulari odierne, basate sulla tecnologia Massive MIMO, possano raggiungere elevate performance in condizioni favorevoli (centro cella) esse, presentano all’interno dell’area di copertura, zone soggette a data-rate notevolmente ridotti. In questo elaborato, viene brevemente descritta la rete cell-free; una nuova architettura di rete pensata per superare i vecchi limiti delle reti cellulari tradizionali. Successivamente, vengono presentati attraverso simulazioni i due principali vantaggi che queste nuove reti cell-free offrono. Inoltre, viene analizzato uno schema random access in grado di gestire l’accesso multiplo per queste nuove architetture di rete. Questo schema rappresenta un’estensione di un protocollo già presente in letteratura e perfettamente funzionante per reti Massive MIMO, appartenente alla famiglia dei protocolli Coded Slotted ALOHA. Infine, un'analisi delle prestazioni e alcuni possibili scenari sono stati presentati, con lo scopo di valutare l'effetto che algoritmi di tipo SIC possono avere su queste reti.

AlmaBike: una piattaforma web per aggregare e visualizzare dati sull'inquinamento da sensori IoT

L'inquinamento è un pensiero costante nel ventunesimo secolo. Ogni anno, i ricercatori cercano di trovare nuove metodologie e tecnologie per controllarlo e ridurlo. Per questo motivo l’Università di Bologna ha avviato svariati progetti per contrastare le problematiche ambientali. Una delle iniziative è AlmaBike. Sono biciclette che vengono assegnate nella forma di comodato gratuito al personale universitario e agli studenti. Nell'ultimo periodo, 50 AlmaBike sono state dotate di un pacchetto sensori in grado di rilevare posizione GPS, la qualità dell’aria, il rumore e alcuni parametri ambientali. Gli obiettivi perseguiti sono: sperimentare un sistema che permetta la misurazione di dati in merito alla qualità ambientale del comune di Bologna e misurare la rilevanza della consapevolezza della qualità dell’aria nella scelta di percorsi da parte di un utente, ad esempio casa-lavoro. L’obiettivo di questa tesi è quello di creare un applicativo che permetta la fruizione dei dati raccolti dai vari sensori attraverso l’uso di tecniche di Data Visualization. I dati vengono elaborati e organizzati con lo scopo di permetterne la comprensione anche ad utenti inesperti. La tesi è suddivisa in tre capitoli: nel primo capitolo sono stati approfonditi i concetti inerenti alla sostenibilità riprendendo quanto detto a proposito degli obiettivi dell'Agenda 2030, facendo anche una breve introduzione sul concetto di IoT e sensori; nel secondo capitolo vengono presentate le tecnologie utilizzate per la realizzazione dell’applicativo tra cui: Docker, MySQL, Angular, Typescript, Golang; nel terzo capitolo viene mostrata nel dettaglio l'applicazione creata: dalle scelte progettuali, fino ad arrivare al risultato finale.

Grant-Free Access for Massive IoT Based on Interference Cancellation and Massive MIMO

Recent years have witnessed an increasing evolution of wireless mobile networks, with an intensive research work aimed at developing new efficient techniques for the future 6G standards. In the framework of massive machine-type communication (mMTC), emerging Internet of Things (IoT) applications, in which sensor nodes and smart devices transmit unpredictably and sporadically short data packets without coordination, are gaining an increasing interest. In this work, new medium access control (MAC) protocols for massive IoT, capable of supporting a non-instantaneous feedback from the receiver, are studied. These schemes guarantee an high time for the acknowledgment (ACK) messages to the base station (BS), without a significant performance loss. Then, an error floor analysis of the considered protocols is performed in order to obtain useful guidelines for the system design. Furthermore, non-orthogonal multiple access (NOMA) coded random access (CRA) schemes based on power domain are here developed. The introduction of power diversity permits to solve more packet collision at the physical (PHY) layer, with an important reduction of the packet loss rate (PLR) in comparison to the number of active users in the system. The proposed solutions aim to improve the actual grant-free protocols, respecting the stringent constraints of scalability, reliability and latency requested by 6G networks.

Sperimentazione della piattaforma IoT Cloud per lo sviluppo di sistemi di monitoraggio

L’Internet of Things (IoT) è un termine utilizzato nel mondo della telecomunicazione che fa riferimento all’estensione di Internet al mondo degli oggetti, che acquisiscono una propria identità, venendo così definiti “intelligenti”. L’uomo in questo ambito avrà sempre meno incidenza sul campo poiché sono le macchine ad interagire tra loro scambiandosi informazioni. Gli ambiti applicativi che comprendono IoT sono innumerevoli ed eterogenei; pertanto, non esiste un'unica soluzione tecnologica che possa coprire qualsiasi scenario. Una delle tecnologie che si prestano bene a svolgere lavori in IoT sono le LoRaWAN. Un punto e una sfida essenziali nell'applicazione della tecnologia LoRaWAN è garantire la massima autonomia dei dispositivi ottenendo il più basso consumo di energia possibile e la ricerca di soluzioni di alimentazione efficienti. L'obiettivo in questo elaborato è quello di realizzare un sistema capace di trasmettere un flusso continuo di informazioni senza l'ausilio e il costante monitoraggio dell'uomo. Viene trattato come controllare dei sensori da remoto e come garantire una migliore autonomia dei dispositivi ottenendo un più basso consumo energetico.

Neural Network based Non Orthogonal Random Access for 6G NTN-IoT

Pervasive and distributed Internet of Things (IoT) devices demand ubiquitous coverage beyond No-man’s land. To satisfy plethora of IoT devices with resilient connectivity, Non-Terrestrial Networks (NTN) will be pivotal to assist and complement terrestrial systems. In a massiveMTC scenario over NTN, characterized by sporadic uplink data reports, all the terminals within a satellite beam shall be served during the short visibility window of the flying platform, thus generating congestion due to simultaneous access attempts of IoT devices on the same radio resource. The more terminals collide, the more average-time it takes to complete an access which is due to the decreased number of successful attempts caused by Back-off commands of legacy methods. A possible countermeasure is represented by Non-Orthogonal Multiple Access scheme, which requires the knowledge of the number of superimposed NPRACH preambles. This work addresses this problem by proposing a Neural Network (NN) algorithm to cope with the uncoordinated random access performed by a prodigious number of Narrowband-IoT devices. Our proposed method classifies the number of colliding users, and for each estimates the Time of Arrival (ToA). The performance assessment, under Line of Sight (LoS) and Non-LoS conditions in sub-urban environments with two different satellite configurations, shows significant benefits of the proposed NN algorithm with respect to traditional methods for the ToA estimation.

Random Access Procedures in 5G IoT via NTN: System level performances

The Internet of Things (IoT) is a critical pillar in the digital transformation because it enables interaction with the physical world through remote sensing and actuation. Owing to the advancements in wireless technology, we now have the opportunity of using their features to the best of our abilities and improve over the current situation. Indeed, the Internet of Things market is expanding at an exponential rate, with devices such as alarms and detectors, smart metres, trackers, and wearables being used on a global scale for automotive and agriculture, environment monitoring, infrastructure surveillance and management, healthcare, energy and utilities, logistics, good tracking, and so on. The Third Generation Partnership Project (3GPP) acknowledged the importance of IoT by introducing new features to support it. In particular, in Rel.13, the 3GPP introduced the so-called IoT to support Low Power Wide Area Networks (LPWAN).As these devices will be distributed in areas where terrestrial networks are not feasible or commercially viable, satellite networks will play a complementary role due to their ability to provide global connectivity via their large footprint size and short service deployment time. In this context, the goal of this thesis is to investigate the viability of integrating IoT technology with satellite communication (SatCom) systems, with a focus on the Random Access(RA) Procedure. Indeed, the RA is the most critical procedure because it allows the UE to achieve uplink synchronisation, obtain the permanent ID, and obtain uplink transmission resources. The goal of this thesis is to evaluate preamble detection in the SatCom environment.

Adozione del framework Arrowhead per l’automazione di scenari IoT: Discovery, Orchestrazione e Coreografia.

In questa tesi approfondiamo l’utilizzo del framework Arrowhead per creare una demo di un sistema per l’automazione IoT industriale. Il framework fornisce dei core specifici per il controllo di un sistema industriale nell’ottica dell’industria 4.0. Nello specifico prendiamo in analisi i tre core principali di Arrowhead, più un quarto, il Choreographer, interessante perchè fornisce servizi non comuni, ma molto utili, per la gestione di sistemi industriali. La demo è stata suddivisa in livelli per permettere un’analisi dettagliata dei vantaggi e delle scelte implementative che l’integrazione dei vari core apporta alla demo. Si è scelto, inoltre, di analizzare separatamente le scelte teoriche e pratiche che sono state effettuate nello sviluppo della demo. In questa tesi, quindi, analizziamo l’integrazione del framework Arrowhead all’interno di un sistema di IoT industriale e porteremo alla luce i vantaggi del suo utilizzo e per quale motivo non risulta essere competitivo nel suo mercato di appartenenza.

RED-Bridge: A Multiprotocol Tool Prototype for IoT Sensors

The IoT is growing more and more each year and is becoming so ubiquitous that it includes heterogeneous devices with different hardware and software constraints leading to an highly fragmented ecosystem. Devices are using different protocols with different paradigms and they are not compatible with each other; some devices use request-response protocols like HTTP or CoAP while others use publish-subscribe protocols like MQTT. Integration in IoT is still an open research topic. When handling and testing IoT sensors there are some common task that people may be interested in: reading and visualizing the current value of the sensor; doing some aggregations on a set of values in order to compute statistical features; saving the history of the data to a time-series database; forecasting the future values to react in advance to a future condition; bridging the protocol of the sensor in order to integrate the device with other tools. In this work we will show the working implementation of a low-code and flow-based tool prototype which supports the common operations mentioned above, based on Node-RED and Python. Since this system is just a prototype, it has some issues and limitations that will be discussed in this work.