Development Of New Toolkits For Orbit Determination Codes For Precise Radio Tracking Experiments

This thesis describes the developments of new models and toolkits for the orbit determination codes to support and improve the precise radio tracking experiments of the Cassini-Huygens mission, an interplanetary mission to study the Saturn system. The core of the orbit determination process is the comparison between observed observables and computed observables. Disturbances in either the observed or computed observables degrades the orbit determination process. Chapter 2 describes a detailed study of the numerical errors in the Doppler observables computed by NASA's ODP and MONTE, and ESA's AMFIN. A mathematical model of the numerical noise was developed and successfully validated analyzing against the Doppler observables computed by the ODP and MONTE, with typical relative errors smaller than 10%. The numerical noise proved to be, in general, an important source of noise in the orbit determination process and, in some conditions, it may becomes the dominant noise source. Three different approaches to reduce the numerical noise were proposed. Chapter 3 describes the development of the multiarc library, which allows to perform a multi-arc orbit determination with MONTE. The library was developed during the analysis of the Cassini radio science gravity experiments of the Saturn's satellite Rhea. Chapter 4 presents the estimation of the Rhea's gravity field obtained from a joint multi-arc analysis of Cassini R1 and R4 fly-bys, describing in details the spacecraft dynamical model used, the data selection and calibration procedure, and the analysis method followed. In particular, the approach of estimating the full unconstrained quadrupole gravity field was followed, obtaining a solution statistically not compatible with the condition of hydrostatic equilibrium. The solution proved to be stable and reliable. The normalized moment of inertia is in the range 0.37-0.4 indicating that Rhea's may be almost homogeneous, or at least characterized by a small degree of differentiation.

Percorsi urbani e percorsi narrativi: il "racconto dei racconti" di via Zamboni a Bologna

La percezione dello spazio urbano, nella sua complessità, risente inevitabilmente dello stratificarsi, nel tempo, di significati storici, ideologie, archetipi e utopie attraverso i quali la società, nei suoi diversi stadi di sviluppo, ha consolidato l'idea di centro abitato. Nel mondo contemporaneo, la città narrata si sovrappone sempre di più a quella reale, organizzando e sintetizzando i processi interpretativi dei circuiti urbani: al cityscape, il panorama fisico della città, si antepone il suo mindscape, il panorama dell'anima e delle culture urbane. In sintonia con tali prospettive, la presente ricerca si propone di analizzare i processi comunicativi e i paradigmi mediatici che attraversano e ridefiniscono le dinamiche urbane, prendendo in esame gli strumenti e i linguaggi che concorrono a disegnare e raccontare l'immagine di una città. In tale contesto, il progetto prende in considerazione come case study la singolare situazione del distretto universitario intorno a via Zamboni a Bologna: un'arteria di straordinaria bellezza e vitalità, cui tuttavia non corrisponde un'immagine pubblica altrettanto positiva. La tesi ha analizzato in particolare l’immagine pubblica e la percezione di via Zamboni e di piazza Verdi dai primi del Novecento a oggi, in relazione ai principali eventi che le hanno viste come scenari privilegiati. Prendendo in considerazione un arco di tempo di oltre un secolo, sono stati selezionati alcuni momenti topici, occasioni culturali o accadimenti con una forte connotazione simbolica: dalla Liberazione alle manifestazioni del ’77, dalle storiche ‘prime’ del Teatro Comunale agli allestimenti della Pinacoteca, dalle lezioni di professori universitari di chiara fama alle più recenti contestazioni studentesche. Il risultato è un racconto stratificato che attraversa segni e immagini per ricostruire l’iconografia del quartiere attraverso testi, fotografie, filmati, opere d’arte o prodotti multimediali.

Modelling and Uncertainty Quantification application to SA simulation codes in advanced SMR

In the framework of a global transition to a low-carbon energy mix, the interest in advanced nuclear Small Modular Reactors (SMRs) has been growing at the international level. Due to the high level of maturity reached by Severe Accident Codes for currently operating rectors, their applicability to advanced SMRs is starting to be studied. Within the present work of thesis and in the framework of a collaboration between ENEA, UNIBO and IRSN, an ASTEC code model of a generic IRIS reactor has been developed. The simulation of a DBA sequence involving the operation of all the passive safety systems of the generic IRIS has been carried out to investigate the code model capability in the prediction of the thermal-hydraulics characterizing an integral SMR adopting a passive mitigation strategy. The following simulation of 4 BDBAs sequences explores the applicability of Severe Accident Codes to advance SMRs in beyond-design and core-degradation conditions. The uncertainty affecting a code simulation can be estimated by using the method of Input Uncertainty Propagation, whose application has been realized through the RAVEN-ASTEC coupling and implementation on an HPC platform. This probabilistic methodology has been employed in a study of the uncertainty affecting the passive safety system operation in the DBA simulation of ASTEC, providing a further characterization of the thermal-hydraulics of this sequence. The application of the Uncertainty Quantification method to early core-melt phenomena has been investigated in the framework of a BEPU analysis of the ASTEC simulation of the QUENCH test-6 experiment. A possible solution to the encountered challenges has been proposed through the application of a Limit Surface search algorithm.