Ημερολόγιο Εκδηλώσεων
Προβολή ημερολογίου
Προβολή λίστας
iCal - Εκδηλώσεις μήνα
RSS - Εκδηλώσεις μήνα26
Ιουν
Κατηγορία:
Παρουσίαση Διπλωματικής Εργασίας
ΗΜΜΥ
Λ - Κτίριο Επιστημών/ΗΜΜΥ, 2041
26/06/2017 11:30 - 12:30Περιγραφή:
ΠΟΛΥΤΕΧΝΕΙΟ ΚΡΗΤΗΣ Σχολή Ηλεκτρολόγων Μηχανικών και Μηχανικών Υπολογιστών Πρόγραμμα Προπτυχιακών Σπουδών ΠΑΡΟΥΣΙΑΣΗ ΔΙΠΛΩΜΑΤΙΚΗΣ ΕΡΓΑΣΙΑΣ Κωνσταντίνου Iορδάνου με θέμα Υλοποίηση των Αλγορίθμων Mutual Information και Transfer Entropy με χρήση Υπέρ-υπολογιστή βασισμένο σε Αναδιατασσόμενη Λογική. Ιmplementation of Mutual Information and Transfer Entropy Algorithms with FPGA-based SuperComputer. Δευτέρα 26 Ιουνίου 2017, 11:30 π.μ. Αίθουσα 2041, Κτίριο Επιστημών, Πολυτεχνειούπολη Εξεταστική Επιτροπή Καθηγητής Απόστολος Δόλλας (επιβλέπων, Σχολή ΗΜΜΥ) Καθηγητής Μίνως Γαροφαλάκης (Σχολή ΗΜΜΥ) Αναπληρωτής Καθηγητής Ιωάννης Παπαευσταθίου (Σχολή ΗΜΜΥ) Abstract It is widely known that contemporary applications are bounded by massive computational demands. With conventional CPUs falling out of favor due to their limitations, the industry of Hybrid-SuperComputers using reconfigurable logic which is a growing field in the area of Computer Systems. This thesis explores the Convey Computer, and more specifically the platform HC-2ex which is a hybrid platform with increased computational capacity as well as a combination of a high-bandwidth memory interface with an architecture featuring multiple levels of computational parallelism. This platform selected in order to efficiently map computationally intensive algorithms in modern hardware. We address two challenging problems within this framework, the first being time-series analysis by focusing on the calculation of the Mutual Information (MI) statistical value and the second being the Transfer Entropy (TE) statistical value between two time-series. The problems of Mutual Information and Transfer Entropy respectively, have been addressed by the research community for low-precision arithmetic applications, but the performance of these algorithms have not been evaluated on platforms like Convey Computer. This is the first work to extensively study of using this platform, by identifying the pros and cons of Convey Computer with computationally intensive algorithms as well as describing how these algorithms can efficiently utilized. In terms of result, Mutual Information and Transfer Entropy implementations compared with implemented architectures on other platforms like Maxeler. Compared to the reference software, the implementation of MI algorithm yielded 13x speedup as well as the implementation of TE yielded 15x speedup for high dimensional data using 32-bit precision arithmetic on Convey HC-2ex.
ΠΟΛΥΤΕΧΝΕΙΟ ΚΡΗΤΗΣ Σχολή Ηλεκτρολόγων Μηχανικών και Μηχανικών Υπολογιστών Πρόγραμμα Προπτυχιακών Σπουδών ΠΑΡΟΥΣΙΑΣΗ ΔΙΠΛΩΜΑΤΙΚΗΣ ΕΡΓΑΣΙΑΣ Κωνσταντίνου Iορδάνου με θέμα Υλοποίηση των Αλγορίθμων Mutual Information και Transfer Entropy με χρήση Υπέρ-υπολογιστή βασισμένο σε Αναδιατασσόμενη Λογική. Ιmplementation of Mutual Information and Transfer Entropy Algorithms with FPGA-based SuperComputer. Δευτέρα 26 Ιουνίου 2017, 11:30 π.μ. Αίθουσα 2041, Κτίριο Επιστημών, Πολυτεχνειούπολη Εξεταστική Επιτροπή Καθηγητής Απόστολος Δόλλας (επιβλέπων, Σχολή ΗΜΜΥ) Καθηγητής Μίνως Γαροφαλάκης (Σχολή ΗΜΜΥ) Αναπληρωτής Καθηγητής Ιωάννης Παπαευσταθίου (Σχολή ΗΜΜΥ) Abstract It is widely known that contemporary applications are bounded by massive computational demands. With conventional CPUs falling out of favor due to their limitations, the industry of Hybrid-SuperComputers using reconfigurable logic which is a growing field in the area of Computer Systems. This thesis explores the Convey Computer, and more specifically the platform HC-2ex which is a hybrid platform with increased computational capacity as well as a combination of a high-bandwidth memory interface with an architecture featuring multiple levels of computational parallelism. This platform selected in order to efficiently map computationally intensive algorithms in modern hardware. We address two challenging problems within this framework, the first being time-series analysis by focusing on the calculation of the Mutual Information (MI) statistical value and the second being the Transfer Entropy (TE) statistical value between two time-series. The problems of Mutual Information and Transfer Entropy respectively, have been addressed by the research community for low-precision arithmetic applications, but the performance of these algorithms have not been evaluated on platforms like Convey Computer. This is the first work to extensively study of using this platform, by identifying the pros and cons of Convey Computer with computationally intensive algorithms as well as describing how these algorithms can efficiently utilized. In terms of result, Mutual Information and Transfer Entropy implementations compared with implemented architectures on other platforms like Maxeler. Compared to the reference software, the implementation of MI algorithm yielded 13x speedup as well as the implementation of TE yielded 15x speedup for high dimensional data using 32-bit precision arithmetic on Convey HC-2ex.
