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dc.contributor.authorChen, Xin
dc.date.accessioned2015-07-21T12:42:01Z
dc.date.available2015-07-21T12:42:01Z
dc.date.issued2015-01-05
dc.identifier.citationChen, X. 2015. ENERGY EFFICIENT WIRED NETWORKING. ENERGY EFFICIENT WIRED NETWORKINGen_US
dc.identifier.urihttp://qmro.qmul.ac.uk/xmlui/handle/123456789/7966
dc.descriptionThe copyright of this thesis rests with the author and no quotation from it or information derived from it may be published without the prior written consent of the authoren_US
dc.description.abstractThis research proposes a new dynamic energy management framework for a backbone Internet Protocol over Dense Wavelength Division Multiplexing (IP over DWDM) network. Maintaining the logical IP-layer topology is a key constraint of our architecture whilst saving energy by infrastructure sleeping and virtual router migration. The traffic demand in a Tier 2/3 network typically has a regular diurnal pattern based on people‟s activities, which is high in working hours and much lighter during hours associated with sleep. When the traffic demand is light, virtual router instances can be consolidated to a smaller set of physical platforms and the unneeded physical platforms can be put to sleep to save energy. As the traffic demand increases the sleeping physical platforms can be re-awoken in order to host virtual router instances and so maintain quality of service. Since the IP-layer topology remains unchanged throughout virtual router migration in our framework, there is no network disruption or discontinuities when the physical platforms enter or leave hibernation. However, this migration places extra demands on the optical layer as additional connections are needed to preserve the logical IP-layer topology whilst forwarding traffic to the new virtual router location. Consequently, dynamic optical connection management is needed for the new framework. Two important issues are considered in the framework, i.e. when to trigger the virtual router migration and where to move virtual router instances to? For the first issue, a reactive mechanism is used to trigger the virtual router migration by monitoring the network state. Then, a new evolutionary-based algorithm called VRM_MOEA is proposed for solving the destination physical platform selection problem, which chooses the appropriate location of virtual router instances as traffic demand varies. A novel hybrid simulation platform is developed to measure the performance of new framework, which is able to capture the functionality of the optical layer, the IP layer data-path and the IP/optical control plane. Simulation results show that the performance of network energy saving depends on many factors, such as network topology, quiet and busy thresholds, and traffic load; however, savings of around 30% are possible with typical medium-sized network topologies.en_US
dc.language.isoenen_US
dc.publisherENERGY EFFICIENT WIRED NETWORKINGen_US
dc.subjectenergy efficiencyen_US
dc.subjectbandwidth-intensive applicationsen_US
dc.subjectInternet Service Providersen_US
dc.subjecttelecommunicationsen_US
dc.subjectdynamic energy management frameworken_US
dc.subjectDense Wavelength Division Multiplexingen_US
dc.subjectinfrastructure sleepingen_US
dc.subjectvirtual router migration.en_US
dc.titleENERGY EFFICIENT WIRED NETWORKINGen_US
dc.typeThesisen_US


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    Theses Awarded by Queen Mary University of London

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