Σκοπός της διατριβής ήταν η μελέτη ενός μέσης κλίμακας καταιγιδοφόρου συστήματος με τη χρήση δορυφορικών δεδομένων του δορυφόρου GPMCoreObservatory. Κυρίως χρησιμοποιήθηκαν οι καινοτόμες τεχνολογίες του δορυφορικού ραντάρ του με το όνομα DPR. Σύμφωνα με αυτά τα δεδομένα μπορέσαμε να εξάγουμε συμπεράσματα για τα στοιχεία μικροφυσικής του καταιγιδοφόρου συστήματος, όπως η διάμετρος και η συγκέντρωση των κατακρημνισμάτων. Επίσης, μελετήθηκαν εις βάθος η ένταση της βροχόπτωσης, η έκτασή της και το ποσό της. Επίσης, για την εξακρίβωση των δεδομένων του δορυφόρου, χρησιμοποιήθηκαν δεδομένα του δορυφόρου MSG, επίγειων ραντάρ, μετεωρολογικών σταθμών ανά την επικράτεια της Ελλάδας και ενός δικτύου καταγραφής ηλεκτρικών εκκενώσεων. Ακόμη έγινε ανάλυση των χαρακτηριστικών της περιβάλλουσας ατμόσφαιρας με τη χρήση συνοπτικών χαρτών σε διάφορα επίπεδα, κατακόρυφων τομών και τρισδιάστατων απεικονίσεων. Τέλος, συμπεράναμε πως τα δεδομένα του GPM μπορούν να δώσουν αξιόπιστα δεδομένα για τη χρήση τους στην πρόγνωση καιρού και στην επιχειρησιακή μετεωρολογία στο μέλλον.

The purpose of this thesis is the investigation of a mesoscale convective system with the use of satellite data of the GPM Core Observatory satellite. Mainly, they have been used the innovative technologies of the precipitation radar named DPR. With the help of this data we could made conclusions about the microphysical characteristics of the convective system, such as the diameter and the concentration of its water droplets. Furthermore, the rain rate, its extend and its amount are studied in depth. Also, for the validation of the satellite data, are used data from the MSG geostationary satellite, ground weather radars, weather stations and a grid of recording electric discharges. Moreover, an analysis of the characteristics of the surrounding atmosphere is made with the use of synoptic charts in various levels, vertical cross sections and three-dimensional visualizations. Finally, we concluded that the GPM’s data can give reliable data for their utilization in weather forecasting and operational weather forecasting in the future.

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