Il Sistema Gateway nello sviluppo della rete del trasporto combinato in Europa: il caso del terminal di Verona Quadrante Europa

Il trasporto intermodale ha acquisito un ruolo sempre più importante nello scenario dei trasporti comunitari merci durante gli ultimi quindici anni. La sfida che si era posta a inizi anni novanta in Europa consisteva nello sviluppo di una rete europea di trasporto combinato strada-ferrovia. A questo fine è stata fondamentale la cooperazione tra gli operatori del settore e le istituzioni (comunitarie e nazionali), nonché l’impulso dato dalla liberalizzazione del trasporto ferroviario, che fortemente influenza il trasporto combinato. Questa tesi, in particolare, intende studiare il ruolo del Sistema Gateway come strumento innovativo e di nuovo impulso per lo sviluppo della rete di trasporto combinato strada-rotaia in ambito europeo. Grazie a questo sistema, le unità di carico, dirette in una determinata regione, giungono ad un "Terminal Gateway", dove secondo un sistema di tipo “hub-and-spoke” vengono trasbordate a mezzo gru su treni “Shuttle” verso la destinazione finale. Tutto ciò avviene con operazioni fortemente automatizzate e veloci con sensibile vantaggio in termini di tempo e costi. La tesi parte da una descrizione del trasporto intermodale, facendo un focus sugli aspetti strutturali, tecnici e organizzativi del trasporto combinato strada – rotaia e del suo funzionamento. Passando attraverso l’analisi delle reti di trasporto merci in Europa, nel secondo capitolo. Il terzo capitolo entra nel vivo della Tesi introducendo l’oggetto dell’indagine: il Sistema Gateway nell’ambito dello sviluppo della rete europea del traffico combinato strada-ferrovia. Nella seconda parte della tesi è voluto studiare il Sistema Gateway con l’ausilio dei metodi d’analisi che vengono applicati per la scelta fra progetti alternativi nel campo della pianificazione dei trasporti, pertanto sono stati presi in rassegna e descritti i metodi più utilizzati: l’Analisi Benefici-Costi e l’Analisi Multicriteria. Nel caso applicativo è stata utilizzata l’Analisi Benefici-Costi. Infine nel capitolo sesto è stato presentato dettagliatamente il caso reale di studio che riguarda il progetto per la trasformazione del terminal di Verona Quadrante Europa in un terminal gateway.

Wireless Sensor Networks for Monitoring Applications

Wireless Sensor Networks (WSNs) are getting wide-spread attention since they became easily accessible with their low costs. One of the key elements of WSNs is distributed sensing. When the precise location of a signal of interest is unknown across the monitored region, distributing many sensors randomly/uniformly may yield with a better representation of the monitored random process than a traditional sensor deployment. In a typical WSN application the data sensed by nodes is usually sent to one (or more) central device, denoted as sink, which collects the information and can either act as a gateway towards other networks (e.g. Internet), where data can be stored, or be processed in order to command the actuators to perform special tasks. In such a scenario, a dense sensor deployment may create bottlenecks when many nodes competing to access the channel. Even though there are mitigation methods on the channel access, concurrent (parallel) transmissions may occur. In this study, always on the scope of monitoring applications, the involved development progress of two industrial projects with dense sensor deployments (eDIANA Project funded by European Commission and Centrale Adritica Project funded by Coop Italy) and the measurement results coming from several different test-beds evoked the necessity of a mathematical analysis on concurrent transmissions. To the best of our knowledge, in the literature there is no mathematical analysis of concurrent transmission in 2.4 GHz PHY of IEEE 802.15.4. In the thesis, experience stories of eDIANA and Centrale Adriatica Projects and a mathematical analysis of concurrent transmissions starting from O-QPSK chip demodulation to the packet reception rate with several different types of theoretical demodulators, are presented. There is a very good agreement between the measurements so far in the literature and the mathematical analysis.

Advanced Beamforming for Distributed and Multi-Beam Networks

Beamforming entails joint processing of multiple signals received or transmitted by an array of antennas. This thesis addresses the implementation of beamforming in two distinct systems, namely a distributed network of independent sensors, and a broad-band multi-beam satellite network. With the rising popularity of wireless sensors, scientists are taking advantage of the flexibility of these devices, which come with very low implementation costs. Simplicity, however, is intertwined with scarce power resources, which must be carefully rationed to ensure successful measurement campaigns throughout the whole duration of the application. In this scenario, distributed beamforming is a cooperative communication technique, which allows nodes in the network to emulate a virtual antenna array seeking power gains in the order of the size of the network itself, when required to deliver a common message signal to the receiver. To achieve a desired beamforming configuration, however, all nodes in the network must agree upon the same phase reference, which is challenging in a distributed set-up where all devices are independent. The first part of this thesis presents new algorithms for phase alignment, which prove to be more energy efficient than existing solutions. With the ever-growing demand for broad-band connectivity, satellite systems have the great potential to guarantee service where terrestrial systems can not penetrate. In order to satisfy the constantly increasing demand for throughput, satellites are equipped with multi-fed reflector antennas to resolve spatially separated signals. However, incrementing the number of feeds on the payload corresponds to burdening the link between the satellite and the gateway with an extensive amount of signaling, and to possibly calling for much more expensive multiple-gateway infrastructures. This thesis focuses on an on-board non-adaptive signal processing scheme denoted as Coarse Beamforming, whose objective is to reduce the communication load on the link between the ground station and space segment.