• DocumentCode
    1627887
  • Title

    Energy Efficient Cloud Computing Environment via Autonomic Meta-director Framework

  • Author

    Baker, Thar ; Ngoko, Yanik ; Tolosana-Calasanz, Rafael ; Rana, Omer F. ; Randles, Martin

  • Author_Institution
    Sch. of Comput. & Math. Sci., Liverpool John Moores Univ., Liverpool, UK
  • fYear
    2013
  • Firstpage
    198
  • Lastpage
    203
  • Abstract
    The ever-increasing density in cloud computing users, services, and data centres has led to significant increases in network traffic and the associated energy consumed by its huge infrastructure, e.g. extra servers, switches, routers, which is required to respond quickly and effectively to users requests. Transferring data, via a high bandwidth connection between data centres and cloud users, consumes even larger amounts of energy than just processing and storing the data on a cloud data centre, and hence producing high carbon dioxide emissions. This power consumption is highly significant when transferring data into a data centre located relatively far from the user´s geographical location. Thus, it became high-necessity to locate the lowest energy consumption route between the user and the designated data centre, while making sure the user´s requirements, e.g. response time, are met. This paper proposes a high-end autonomic meta-director framework to find the most energy efficient route to the green data centre by utilising the linear programming approach. The framework is, first, formalised by the situation calculus, and then evaluated against shortest path algorithm with minimum number of nodes traversed.
  • Keywords
    cloud computing; computer centres; energy conservation; green computing; linear programming; power aware computing; power consumption; autonomic metadirector framework; carbon dioxide emissions; cloud data centres; data transfer; energy consumption route; energy efficient cloud computing environment; green data centre; linear programming approach; power consumption; shortest path algorithm; situation calculus; Cloud computing; Data models; Educational institutions; Energy consumption; Green products; Logic gates; Power demand; Cloud Computing; Energy Efficiency; Routing Algorithms;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Developments in eSystems Engineering (DeSE), 2013 Sixth International Conference on
  • Conference_Location
    Abu Dhabi
  • ISSN
    2161-1343
  • Print_ISBN
    978-1-4799-5263-2
  • Type

    conf

  • DOI
    10.1109/DeSE.2013.43
  • Filename
    7041116