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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

An Energy-Efficient Reservation Framework for Large-Scale Distributed Systems

Orgerie, Anne-Cécile 27 September 2011 (has links) (PDF)
Over the past few years, the energy consumption of Information and Communication Technologies (ICT) has become a major issue. Nowadays, ICT accounts for 2% of the global CO2 emissions, an amount similar to that produced by the aviation industry. Large-scale distributed systems (e.g. Grids, Clouds and high-performance networks) are often heavy electricity consumers because -- for high-availability requirements -- their resources are always powered on even when they are not in use. Reservation-based systems guarantee quality of service, allow for respect of user constraints and enable fine-grained resource management. For these reasons, we propose an energy-efficient reservation framework to reduce the electric consumption of distributed systems and dedicated networks. The framework, called ERIDIS, is adapted to three different systems: data centers and grids, cloud environments and dedicated wired networks. By validating each derived infrastructure, we show that significant amounts of energy can be saved using ERIDIS in current and future large-scale distributed systems.
2

An Energy-Efficient Reservation Framework for Large-Scale Distributed Systems / Un environnement de réservation efficace en énergie pour les systèmes distribués à grande échelle

Orgerie, Anne-Cécile 27 September 2011 (has links)
Depuis quelques années, économiser l'énergie est devenu un enjeu majeur dans les technologies de l'information et de la communication (TIC). Celles-ci représentent en effet 2% des émissions de CO2 de la planète, soit autant que l'aviation. Les systèmes distribués (grilles, clouds, réseaux haute performance) constituent de gros consommateurs d'électricité. En effet, pour des besoins de haute disponibilité, leurs ressources sont allumées en permanence et notamment lorsqu'elles ne sont pas utilisées. Les systèmes de réservation garantissent qualité de service et respect des contraintes de l'utilisateur. Ils permettent également une gestion plus fine des ressources. Pour limiter la consommation électrique des systèmes distribués et des réseaux dédiés, nous avons proposé un système de réservation de ressources efficace en énergie. Ce système de réservation, appelé ERIDIS, a été adapté à trois infrastructures distribuées différentes: les centres de calcul et les grilles, les environnements de cloud et les réseaux filaires dédiés. Dans les trois cas, des validations ont été menées et elles ont montré que des économies d'énergie significatives pouvaient être réalisées en utilisant ERIDIS dans les systèmes distribués actuels et futurs. / Over the past few years, the energy consumption of Information and Communication Technologies (ICT) has become a major issue. Nowadays, ICT accounts for 2% of the global CO2 emissions, an amount similar to that produced by the aviation industry. Large-scale distributed systems (e.g. Grids, Clouds and high-performance networks) are often heavy electricity consumers because -- for high-availability requirements -- their resources are always powered on even when they are not in use. Reservation-based systems guarantee quality of service, allow for respect of user constraints and enable fine-grained resource management. For these reasons, we propose an energy-efficient reservation framework to reduce the electric consumption of distributed systems and dedicated networks. The framework, called ERIDIS, is adapted to three different systems: data centers and grids, cloud environments and dedicated wired networks. By validating each derived infrastructure, we show that significant amounts of energy can be saved using ERIDIS in current and future large-scale distributed systems.

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