Cross-layer optimizations in multi-hop ad hoc networks

Unlike traditional wireless networks, characterized by the presence of last-mile, static and reliable infrastructures, Mobile ad Hoc Networks (MANETs) are dynamically formed by collections of mobile and static terminals that exchange data by enabling each other's communication. Supporting multi-hop communication in a MANET is a challenging research area because it requires cooperation between different protocol layers (MAC, routing, transport). In particular, MAC and routing protocols could be considered mutually cooperative protocol layers. When a route is established, the exposed and hidden terminal problems at MAC layer may decrease the end-to-end performance proportionally with the length of each route. Conversely, the contention at MAC layer may cause a routing protocol to respond by initiating new routes queries and routing table updates. Multi-hop communication may also benefit the presence of pseudo-centralized virtual infrastructures obtained by grouping nodes into clusters. Clustering structures may facilitate the spatial reuse of resources by increasing the system capacity: at the same time, the clustering hierarchy may be used to coordinate transmissions events inside the network and to support intra-cluster routing schemes. Again, MAC and clustering protocols could be considered mutually cooperative protocol layers: the clustering scheme could support MAC layer coordination among nodes, by shifting the distributed MAC paradigm towards a pseudo-centralized MAC paradigm. On the other hand, the system benefits of the clustering scheme could be emphasized by the pseudo-centralized MAC layer with the support for differentiated access priorities and controlled contention. In this thesis, we propose cross-layer solutions involving joint design of MAC, clustering and routing protocols in MANETs. As main contribution, we study and analyze the integration of MAC and clustering schemes to support multi-hop communication in large-scale ad hoc networks. A novel clustering protocol, named Availability Clustering (AC), is defined under general nodes' heterogeneity assumptions in terms of connectivity, available energy and relative mobility. On this basis, we design and analyze a distributed and adaptive MAC protocol, named Differentiated Distributed Coordination Function (DDCF), whose focus is to implement adaptive access differentiation based on the node roles, which have been assigned by the upper-layer's clustering scheme. We extensively simulate the proposed clustering scheme by showing its effectiveness in dominating the network dynamics, under some stressing mobility models and different mobility rates. Based on these results, we propose a possible application of the cross-layer MAC+Clustering scheme to support the fast propagation of alert messages in a vehicular environment. At the same time, we investigate the integration of MAC and routing protocols in large scale multi-hop ad-hoc networks. A novel multipath routing scheme is proposed, by extending the AOMDV protocol with a novel load-balancing approach to concurrently distribute the traffic among the multiple paths. We also study the composition effect of a IEEE 802.11-based enhanced MAC forwarding mechanism called Fast Forward (FF), used to reduce the effects of self-contention among frames at the MAC layer. The protocol framework is modelled and extensively simulated for a large set of metrics and scenarios. For both the schemes, the simulation results reveal the benefits of the cross-layer MAC+routing and MAC+clustering approaches over single-layer solutions.

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.

Dye doped, core / shell silica nanoparticles: synthesis, characterization, & biotechnological applications

The aim of this thesis was to design, synthesize and develop a nanoparticle based system to be used as a chemosensor or as a label in bioanalytical applications. A versatile fluorescent functionalizable nanoarchitecture has been effectively produced based on the hydrolysis and condensation of TEOS in direct micelles of Pluronic® F 127, obtaining highly monodisperse silica - core / PEG - shell nanoparticles with a diameter of about 20 nm. Surface functionalized nanoparticles have been obtained in a one-pot procedure by chemical modification of the hydroxyl terminal groups of the surfactant. To make them fluorescent, a whole library of triethoxysilane fluorophores (mainly BODIPY based), encompassing the whole visible spectrum has been synthesized: this derivatization allows a high degree of doping, but the close proximity of the molecules inside the silica matrix leads to the development of self - quenching processes at high doping levels, with the concomitant fall of the fluorescence signal intensity. In order to bypass this parasite phenomenon, multichromophoric systems have been prepared, where highly efficient FRET processes occur, showing that this energy pathway is faster than self - quenching, recovering the fluorescence signal. The FRET efficiency remains very high even four dye nanoparticles, increasing the pseudo Stokes shift of the system, attractive feature for multiplexing analysis. These optimized nanoparticles have been successfully exploited in molecular imaging applications such as in vitro, in vivo and ex vivo imaging, proving themselves superior to conventional molecular fluorophores as signaling units.