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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Κατανεμημένος έλεγχος κυκλοφορίας με σκοπό τη βελτιστοποίηση των συνθηκών ασφάλειας

Θεοδοσίου, Ιωάννης, Μπάλλας, Κωνσταντίνος 15 December 2014 (has links)
Σκοπός αυτής της διπλωματικής εργασίας είναι να αναπτυχθεί ένα μοντέλο αποφυγής συγκρόυσεων μεταξύ των οχημάτων μέσω της επικοινωνίας αυτών. Το σύστημα αυτό θα πρέπει να αναγνωρίζει τις περιπτώσεις που εγκυμονούν κίνδυνο μέσω της ανταλλαγής μηνυμάτων από τα οχήματα κάθε χρονική στιγμή και μέσα από διάφορους μηχανισμούς που επιτελούνται από αυτό, τελικά, να επεμβαίνει και να αποτρέπει τη σύγκρουση ή να ειδοποιεί τον οδηγό ώστε αυτός να αντιδράσει εγκαίρως. Για να το πετύχουμε αυτό ακολουθήσαμε τα εξής βήματα: 1. Προσομοιώσαμε τη λειτουργία μίας συσκευής GPS. 2. Σχεδιάσαμε λεκτικά και γραφικά τα μοντέλα κίνησης στα οποία θα τρέχει το σύστημά μας. 3. Ορίσαμε ένα πρωτόκολλο ανταλλαγής μηνυμάτων και προειδοποίησης σε περίπτωση συγκρουσης για αυτά τα μοντέλα κίνησης. 4. Αναπτύξαμε το σύστημα μέσω της matlab, λαμβάνοντας υπόψιν το πρωτόκολλο και τα σενάρια κίνησης των προηγούμενων βημάτων. 5. Κατασκευάσαμε μία διεπαφή εποπτίας και ελέγχου όλου του συστήματος. 6. Τέλος, κατασκευάσαμε ένα GUI ειδοποίησης του οδηγού σε περιπτώσεις κινδύνου. / Distributed traffic Control for Optimisation of the Safety Conditions.
2

Safety of Cooperative Automated Driving : Analysis and Optimization

Sidorenko, Galina January 2022 (has links)
New cooperative intelligent transportation system (C-ITS) applications become enabled thanks to advances in communication technologies between vehicles(V2V) and with the infrastructure (V2I). Communicating vehicles share information with each other and cooperate, which results in improved safety, fuel economy, and traffic efficiency. An example of a C-ITS application is platooning, which comprises a string of vehicles that travel together with short inter-vehicle distances (IVDs). Any solution related to C-ITS must comply with high safety requirements in order to pass standardization and be commercially deployed. Furthermore, trusted safety levels should be assured even for critical scenarios. This thesis studies the conditions that guarantee safety in emergency braking scenarios for heterogeneous platooning, or string-like, formations of vehicles. In such scenarios, the vehicle at the head of the string emergency brakes and all following vehicles have to automatically react in time to avoid rear-end collisions. The reaction time can be significantly decreased with vehicle-to-vehicle (V2V) communication usage since the leader can explicitly inform other platooning members about the critical braking. The safety analysis conducted in the thesis yields computationally efficient methods and algorithms for calculating minimum inter-vehicle distances that allow avoiding rear-end collisions with a predefined high guarantee. These IVDs are theoretically obtained for an open-loop and a closed-loop configurations. The former implies that follower drives with a constant velocity until braking starts, whereas in the latter, an adaptive cruise control (ACC) with a constant-distance policy serves as a controller. In addition, further optimization of inter-vehicle distances in the platoon is carried out under an assumption of centralized control. Such an approach allows achieving better fuel consumption and road utilization. The performed analytical comparison suggests that our proposed V2V communication based solution is superior to classical automated systems, such as automatic emergency braking system (AEBS), which utilizes only onboard sensors and no communication. Wireless communication, enabling to know the intentions of other vehicles almost immediately, allows for smaller IVDs whilst guaranteeing the same level of safety. Overall, the presented thesis highlights the importance of C-ITS and, specifically, V2V in the prevention of rear-end collisions in emergency scenarios. Future work directions include an extension of the obtained results by considering more advanced models of vehicles, environment, and communication settings; and applying the proposed algorithms of safety guaranteeing to other controllers, such as ACC with a constant time headway policy.

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