• DocumentCode
    1758888
  • Title

    Predictive green wireless access: exploiting mobility and application information

  • Author

    Abou-zeid, Hatem ; Hassanein, Hossam S.

  • Author_Institution
    Electr. & Comput. Eng., Queen´s Univ., Kingston, ON, Canada
  • Volume
    20
  • Issue
    5
  • fYear
    2013
  • fDate
    41548
  • Firstpage
    92
  • Lastpage
    99
  • Abstract
    The ever increasing mobile data traffic and dense deployment of wireless networks have made energy efficient radio access imperative. As networks are designed to satisfy peak user demands, radio access energy can be reduced in a number of ways at times of lower demand. This includes putting base stations (BSs) to intermittent short sleep modes during low load, as well as adaptively powering down select BSs completely where demand is low for prolonged time periods. In order to fully exploit such energy conserving mechanisms, networks should be aware of the user temporal and spatial traffic demands. To this end, this article investigates the potential of utilizing predictions of user location and application information as a means to energy saving. We discuss the development of a predictive green wireless access (PreGWA) framework and identify its key functional entities and their interaction. To demonstrate the potential energy savings we then provide a case study on stored video streaming and illustrate how exploiting predictions can minimize BS resource consumption within a single cell, and across a network of cells. Finally, to emphasize the practical potential of PreGWA, we present a distributed heuristic that reduces resource consumption significantly without requiring considerable information or signaling overhead.
  • Keywords
    mobility management (mobile radio); radio access networks; telecommunication traffic; BS resource consumption; PreGWA framework; application information; base stations; dense deployment; distributed heuristic; energy conserving mechanisms; energy efficiency; energy savings; mobile data traffic; mobility information; predictive green wireless access; radio access energy; radio access imperative; spatial traffic demand; user location prediction; user temporal traffic demand; video streaming; wireless networks; Data processing; Energy efficiency; Green products; Resource management; Streaming media; Telecommunication traffic; Wireless communication; Wireless networks;
  • fLanguage
    English
  • Journal_Title
    Wireless Communications, IEEE
  • Publisher
    ieee
  • ISSN
    1536-1284
  • Type

    jour

  • DOI
    10.1109/MWC.2013.6664479
  • Filename
    6664479