异构多处理器实时系统中一种新的热约束能量感知分区算法

2014 IEEE 33rd International Performance Computing and Communications Conference (IPCCC) Pub Date : 2014-12-01 DOI:10.1109/PCCC.2014.7017092

B. Barrefors, Ying Lu, Shivashis Saha, J. Deogun

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引用次数: 6

摘要

下一代多处理器实时系统以提高功率密度为代价消耗更少的能量。功率密度的增加会导致高热密度，并可能影响实时系统的可靠性和性能。因此，在实时任务集调度中引入最大温度约束是一个重要的挑战。研究了异构多处理器系统中周期性实时任务热约束能量感知分配的新算法。在设计我们的新算法时，我们应用了从一个著名的背包问题解决方案中获得的见解。仿真和实验结果表明，该算法可以显著降低多处理器实时系统的总能耗。

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A novel thermal-constrained energy-aware partitioning algorithm for heterogeneous multiprocessor real-time systems

Next-generation multiprocessor real-time systems consume less energy at the cost of increased power density. This increase in power density results in high heat density and may affect the reliability and performance of real-time systems. Thus, incorporating maximum temperature constraints in scheduling of real-time task sets is an important challenge. This paper investigates a novel algorithm for thermal-constrained energy-aware partitioning of periodic real-time tasks in heterogeneous multiprocessor systems. When designing our new algorithm, we have applied insights gained from a famous knapsack problem solution. Both simulation and experimental results show that our new branch-and-bound based partitioning algorithm can significantly reduce the total energy consumption of multiprocessor real-time systems.

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2014 IEEE 33rd International Performance Computing and Communications Conference (IPCCC)

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