Document Type
Dissertation
Degree
Doctor of Philosophy (PhD)
Major/Program
Computer Science
First Advisor's Name
Raju Rangaswami
First Advisor's Committee Title
Committee Chair
Second Advisor's Name
Ajay Gulati
Third Advisor's Name
Kaushik Dutta
Fourth Advisor's Name
Ming Zhao
Fifth Advisor's Name
Giri Narasimhan
Keywords
storage, energy, memory, disk, non-blocking writes
Date of Defense
7-16-2012
Abstract
Electrical energy is an essential resource for the modern world. Unfortunately, its price has almost doubled in the last decade. Furthermore, energy production is also currently one of the primary sources of pollution. These concerns are becoming more important in data-centers. As more computational power is required to serve hundreds of millions of users, bigger data-centers are becoming necessary. This results in higher electrical energy consumption. Of all the energy used in data- centers, including power distribution units, lights, and cooling, computer hardware consumes as much as 80%. Consequently, there is opportunity to make data-centers more energy efficient by designing systems with lower energy footprint. Consuming less energy is critical not only in data-centers. It is also important in mobile devices where battery-based energy is a scarce resource. Reducing the energy consumption of these devices will allow them to last longer and re-charge less frequently.
Saving energy in computer systems is a challenging problem. Improving a sys- tem’s energy efficiency usually comes at the cost of compromises in other areas such as performance or reliability. In the case of secondary storage, for example, spinning-down the disks to save energy can incur high latencies if they are accessed while in this state. The challenge is to be able to increase the energy efficiency while keeping the system as reliable and responsive as before.
This thesis tackles the problem of improving energy efficiency in existing systems while reducing the impact on performance. First, we propose a new technique to achieve fine grained energy proportionality in multi-disk systems; Second, we design and implement an energy-efficient cache system using flash memory that increases disk idleness to save energy; Finally, we identify and explore solutions for the page fetch-before-update problem in caching systems that can: (a) control better I/O traffic to secondary storage and (b) provide critical performance improvement for energy efficient systems.
Identifier
FI12080621
Recommended Citation
Useche, Luis Enrique, "Optimizing Storage and Memory Systems for Energy and Performance" (2012). FIU Electronic Theses and Dissertations. 698.
https://digitalcommons.fiu.edu/etd/698
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