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Využití protokolu TCP v simulačním prostředí OPNET Modeler / Application of TCP in OPNET Modeler simulation environmentTirinda, Viktor January 2008 (has links)
This diploma thesis describes a possibility of application protocol implementation in OPNET Modeler simulation environment. It presumes that this application protocol is going to use TCP protocol for their communication on transport layer. The first part of thesis is focused on a description of TCP. It is a connection oriented, reliable and confirmed protocol which maintains sequence of transmitted data. This data is after receiving positively confirmed. In the second chapter are described the main functions of OPNET Modeler simulation environment. OPNET is hierarchical divided into four editors. Each editor has a specific function by creating a network and setting his behavior. There is also focused on the two lowest layers of OPNET Modeler and their components in detail, which are participating at usage TCP on transport layer to communication. Implemented applications communicate by sockets, which are created and destroyed on request. Communication is controlled by manager process, whose function is maintenance particular connections and redirect dataflow into relevant process. This manager put in action as well a process, which simulates a single TCP. In the practical part I made two applications: one is a client type and a second one is a server type. Both applications are using TCP on transport layer. The establishment of connection initiates a client, who is sending a request to the server for a data. Then server sends back data in desired quantity. After sending the entire data, client terminates the connection. The result of simulation is statistics, where we pictured the size of the transferred data, a number of transferred packets and other parameters typical for TCP.
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Analysis of network management protocols in optical networksLim, Kok Seng 03 1900 (has links)
Approved for public release, distribution is unlimited / In this thesis, the scalability issues of Simple Network Management Protocol (SNMP) in optical network management are explored. It is important to understand the effect of varying the number of nodes, the request inter-arrival times and the polling interval on the performance of SNMP and number of nodes that can be effectively managed. The current study explored the effect of varying these parameters in a controlled test environment using the OPNET simulation package. In addition, traffic analysis was performed on measured SNMP traffic and statistics were developed from the traffic analysis. With this understanding of SNMP traffic, an SNMPv1 model was defined and integrated into an OPNET network model to study the performance of SNMP. The simulation results obtained were useful in providing needed insight into the allowable number of nodes an optical network management system can effectively manage. / Civilian, Singapore Ministry of Defense
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Μελέτη αρχιτεκτονικής υπηρεσιών-QoS πάνω σε τηλεπικοινωνιακά δίκτυα νέας γενιάς (NGN) (με χρήση εξομοιωτή OPNET)Ανδριοπούλου, Φωτεινή 20 October 2010 (has links)
Οι οικονομικές και τεχνολογικές εξελίξεις των τελευταίων ετών, η απελευθέρωση της αγοράς, οι ισχυρές κατά απαίτηση πολυμεσικές υπηρεσίες καθώς και ο αυξημένος αριθμός χρηστών των κινητών δικτύων υποδεικνύουν την αναγκαιότητα της σύγκλισης των δύο δικτυακών τεχνολογιών (κινητή τηλεφωνία και internet) με στόχο την παροχή υπηρεσιών Internet στο περιβάλλον των κινητών επικοινωνιών. Η παραπάνω απαίτηση οδήγησε στην δημιουργία του δικτύου επόμενης γενιάς NGN.
Η διπλωματική αυτή εργασία ασχολείται με την μελέτη της αρχιτεκτονικής του επιπέδου υπηρεσιών και την υποστήριξη Ποιότητας Υπηρεσίας (QoS) σε δίκτυα Νέας Γενιάς. Συγκεκριμένα δίνεται έμφαση στις λειτουργίες ελέγχου, σηματοδοσίας και λειτουργιών αρχιτεκτονικής του QoS σε επίπεδο υπηρεσιών. Αρχικά, ορίζουμε την έννοια “QoS” όσον αφορά την οπτική του δικτύου και το χρήστη. Περιγράφονται η αρχιτεκτονική του στρώματος υπηρεσιών του δικτύου καθώς και οι λειτουργίες ελέγχου πόρου και αποδοχής των κλήσεων, που αποτελούν σημαντικό μέρος της αρχιτεκτονικής του NGN. Στη συνέχεια παρουσιάζονται αρχιτεκτονικές που προορίζονται για την παροχή του QoS (IntServ, DiffServ), στη Συμφωνία Στάθμης Παρεχόμενης Υπηρεσίας (SLA), το πρωτόκολλο σηματοδοσίας COPS. Επίσης, δίνουμε έμφαση σε ορισμένες πτυχές (χρονοδρομολόγηση, διαχείριση ουρών) μίας QoS αρχιτεκτονικής, οι οποίες είναι ζωτικής σημασίας όσον αφορά την αποδοτική παροχή Ποιότητας Υπηρεσίας. Στη συνέχεια, με τη χρήση του εργαλείου προσομοίωσης OPNET, διεξάγουμε μια σειρά προσομοιώσεων σε ένα ATM και σε ένα NGN δίκτυο. Τέλος, παραθέτουμε και αναλύουμε τα αποτελέσματα των προαναφερθέντων πειραμάτων. / The concept of an NGN (Next Generation Network) has been introduced to take into consideration the new realities in the telecommunications industry, characterized by factors such as: competition among operators due to ongoing deregulation of markets, explosion of digital traffic, e.g.,increasing use of "the Internet", increasing demand for new multimedia services, increasing demand for a general mobility, convergence of networks and services, etc.
This thesis has as subject the architecture of service stratum and presents an overview of standards functions defining the Quality of Service (QoS) in Next Generation Networks (NGNs). Several standards bodies define the QoS control architectures based on their scope of work. Specifically, emphasis is given to control functions, signalling and functional architecture of QoS in service stratum. Firstly, we define the meaning of QoS according to the view of the operator’s network and terminal users. The functional architecture of service stratum and especially the part of resource and admission control functions are described in the main body. Furthermore, architectures as IntServ and DiffServ, SLAs and COPS protocol are used as providers of the QoS. Scheduling and queuing management are necessary to optimize the QoS in NGN networks. In this project, we use OPNET simulator in two scenarios to determine construct and control ATM and NGN networks. Finally, collect the results of the experiments and analyze them.
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