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Design and Development of a Framework for Traffic Management in a Global Manufacturing Enterprise: The American Standard Case StudyMelby, Nathaniel J. 25 January 2015 (has links)
Managed Bandwidth Services (MBSs) use Quality of Service (QoS) guarantees to effectively control traffic flows and reduce network delay. In the past, the provision of MBS in a global manufacturing enterprise was a difficult task for network administrators. However, advances in recently emerging technologies, such as Multiprotocol Label Switching (MPLS), Generalized Multiprotocol Label Switching (GMPLS), Integrated Services (IntServ), Differentiated Services (DiffServ), and Constraint-based Routing (CBR), hold promise to make MBS implementation more manageable. QoS technologies, such as DiffServ and IntServ, offer the benefits of better application performance and delivery of reliable network service. As a consequence of network traffic loads, packet congestion and latency increases still exist and must be addressed by enterprises that intend to support an MBS solution. In this investigation, the author addressed an issue that is faced by many large manufacturing enterprises, i.e., the addition of latency and congestion sensitive traffic such as Voice-over-Internet Protocol (VoIP) to networks with limited bandwidth. The goal of this research was to provide global manufacturing enterprises with a model for bandwidth management in their offices and plants. This model was based on findings from a case study of traffic management at American Standard Companies.
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The modelling of TCP traffic in MPLS networksVillet, Marcel 04 1900 (has links)
Thesis (MSc)--Stellenbosch University, 2003. / ENGLISH ABSTRACT: The Internet has experienced tremendous growth in the last three decades and has emerged as a
platform to carryall forms of communications including voice, video and data. Along with this
growth came the urgency for quality of service (QoS) controls in IP networks as different types of
traffics have different service requirements. Although the IP protocol is able to scale to very large
networks, it does not provide sufficient functionality for traffic engineering in order to enable QoS
control.
Multi-protocol label switching (MPLS) is a new routing technology that enhances IP with some
QoS concepts from ATM and uses relatively simple packet forwarding mechanisms. MPLS has the
ability to perform traffic engineering and QoS control by routing traffic flowson virtual connections
called label switched paths (LSPs) which are assigned capacity.
A large portion of the traffic carried on the Internet consists of data traffic in the form of TCP
traffic. This thesis investigates several TCP models to find the ones most suitable to represent
TCP traffic in MPLS networks. The models consist of three types. The first type models a single
TCP source and the second type models a fixed number of TCP sources. The third type models
an infinite number of TCP sources. The models were evaluated by comparing their throughput
predictions and results obtained from simulation experiments that were done with the widely-used
simulator ns. We also present a simple derivation of the 1/,;e law for the TCP congestion window
size where e is the packet loss probability. / AFRIKAANSE OPSOMMING:In die afgelope drie dekades het die Internet beduidende groei ervaar, soveel so dat dit ontluik het
as 'n medium om alle tipes van moderne kommunikasies te hanteer insluitend telefoon, video en
data. Hierdie groei het gepaard gegaan met die behoefte na diensvlak (QoS) meganismes in IP
netwerke aangesien verskillende tipe kommunikasies verskillende diens vereistes het. Alhoewel die
IP protokol skalleerbaar is tot baie groot netwerke, voorsien dit nie voldoende funksionaliteit om
QoS beheer toe te pas nie.
"Multi-protocol label switching" (MPLS) is 'n nuwe roeterings tegnologie wat IP aanvul met QoS
konsepte van ATM en dit maak gebruik van relatief eenvoudige pakkie versendings-meganismes.
MPLS het die vermoe om netwerk-verkeer reeling en QoS beheer toe te pas deur verkeers-strome
te roeteer op virtuele roetes genaamd "label switched paths" (LSPs) aan wie kapasiteit toegeken
is.
'n Beduidende gedeelte van Internet-verkeer bestaan uit TCP-verkeer. Hierdie tesis ondersoek
verskillende modelle van TCP om die te vind wat die mees geskik is om TCP verkeer in MPLS
netwerke te verteenwoordig. Drie tipes modelle is ondersoek. Die eerste tipe moduleer 'n enkele
TCP verkeersbron en die tweede tipe moduleer 'n vasgestelde aantal TCP verkeersbronne. Die
derde tipe moduleer 'n oneindige aantal verkeersbronne. Die modelle is geevalueer deur hul voorspellings
van die tempo van data transmissie te vergelyk met resultate van simulasies. Die simulasies
is gedoen met die veelgebruikte simulator ns. Hierdie tesis bevat ook 'n eenvoudige afleiding
vir die 1/,;e wet vir die TCP oorlading venster grootte met e die verlies waarskeinlikheid van 'n
netwerk pakkie.
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Intelligent based Packet Scheduling Scheme using Internet Protocol/Multi-Protocol Label Switching (IP/MPLS) Technology for 5G. Design and Investigation of Bandwidth Management Technique for Service-Aware Traffic Engineering using Internet Protocol/Multi-Protocol Label Switching (IP/MPLS) for 5GMustapha, Oba Z. January 2019 (has links)
Multi-Protocol Label Switching (MPLS) makes use of traffic engineering (TE)
techniques and a variety of protocols to establish pre-determined highly
efficient routes in Wide Area Network (WAN). Unlike IP networks in which
routing decision has to be made through header analysis on a hop-by-hop
basis, MPLS makes use of a short bit sequence that indicates the forwarding
equivalence class (FEC) of a packet and utilises a predefined routing table to
handle packets of a specific FEC type. Thus header analysis of packets is not
required, resulting in lower latency. In addition, packets of similar
characteristics can be routed in a consistent manner. For example, packets
carrying real-time information can be routed to low latency paths across the
networks. Thus the key success to MPLS is to efficiently control and distribute
the bandwidth available between applications across the networks.
A lot of research effort on bandwidth management in MPLS networks has
already been devoted in the past. However, with the imminent roll out of 5G,
MPLS is seen as a key technology for mobile backhaul. To cope with the 5G
demands of rich, context aware and multimedia-based user applications, more
efficient bandwidth management solutions need to be derived.
This thesis focuses on the design of bandwidth management algorithms, more
specifically QoS scheduling, in MPLS network for 5G mobile backhaul. The
aim is to ensure the reliability and the speed of packet transfer across the
network. As 5G is expected to greatly improve the user experience with
innovative and high quality services, users’ perceived quality of service (QoS)
needs to be taken into account when deriving such bandwidth management
solutions. QoS expectation from users are often subjective and vague. Thus
this thesis proposes the use of fuzzy logic based solution to provide service aware and user-centric bandwidth management in order to satisfy
requirements imposed by the network and users.
Unfortunately, the disadvantage of fuzzy logic is scalability since dependable
fuzzy rules and membership functions increase when the complexity of being
modelled increases. To resolve this issue, this thesis proposes the use of neuro-fuzzy to solicit interpretable IF-THEN rules.The algorithms are
implemented and tested through NS2 and Matlab simulations. The
performance of the algorithms are evaluated and compared with other
conventional algorithms in terms of average throughput, delay, reliability, cost,
packet loss ratio, and utilization rate.
Simulation results show that the neuro-fuzzy based algorithm perform better
than fuzzy and other conventional packet scheduling algorithms using IP and
IP over MPLS technologies. / Tertiary Education Trust Fund (TETFUND)
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