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Type of Document	Dissertation
Author	Mochocki, Bren Christopher
Author's Email Address	bmochock@nd.edu
URN	etd-12052006-163806
Title	The Impact of Dynamic Voltage and Frequency Scaling on the Energy Consumption, Schedulability and Predictability of Real-Time Embedded Systems
Degree	Doctor of Philosophy
Department	Computer Science and Engineering
Advisory Committee	Advisor Name Title Bruce A. Bunker Committee Chair Aaron D Striegel Committee Member Christian Poellabauer Committee Member Surendar Chandra Committee Member Xiaobo Sharon Hu Committee Member
Keywords	low-power embedded systems 3D graphics real-time
Date of Defense	2006-11-30
Availability	restricted
Abstract Dynamic Voltage and Frequency Scaling (DVFS) has become an accepted and widespread technique to manage power and energy consumption in general-purpose and embedded systems. The careful selection of voltage levels and operating frequencies through DVFS can result in an efficient system that meets deadline, throughput and other timing constraints, while also maximizing the system�s lifetime. However, the misuse of DVFS is also possible, which can result in a system that is either less efficient, or fails to meet timing constraints. In the case of a hard real-time system, this can result in catastrophic failures. This dissertation extends the state-of-the-art in several areas with respect to DVFS. First, several algorithms are introduced to manage the impact of voltage transition overhead on hard real-time systems, including reducing the increase in energy and eliminating deadline misses. Jitter constraints are also met through DVFS to increase the stability and predictability of such systems. In addition to a single CPU, a dual-resource system consisting of a CPU and a wireless network interface is also examined. Next, the applicability of DVFS as a power-management technique for real-time 3D graphics applications on portable embedded systems is evaluated and an effective graphics-workload prediction technique used to facilitate DVFS is introduced. Finally, the simulation platform used to evaluate each of the proposed techniques is presented. Many open problems are presented along the way which can serve as starting points for future research.
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