SolarCore:太阳能驱动的多核架构电源管理

Chao Li, Wangyuan Zhang, Chang-Burm Cho, Tao Li
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引用次数: 94

摘要

全球能源危机和环境问题(例如全球变暖)已推动资讯科技界进入绿色计算时代。在清洁的可再生能源中,太阳能是最有前途的。虽然人们已经在努力提高每瓦特的性能,但传统的架构电源管理方案会导致严重的太阳能损失,因为它们主要是工作负载驱动的,并且不知道供应侧的属性。现有的太阳能收集技术提高了能源利用率,但由于包含大型电池,增加了环境负担和资本投资。此外,如果没有适当的负载适应,太阳能收集本身无法保证高性能。为此,我们提出了SolarCore,这是一种太阳能驱动的多核架构电源管理方案,结合了最大功率供应控制和工作负载运行时优化。利用不同地理位置和季节的真实气象数据,我们表明SolarCore能够在各种环境条件下自主实现太阳能电池板的最佳运行状态(例如最大功率点),平均绿色能源利用率高达82%。我们提出了一种有效的启发式方法来分配时变太阳能在多个核心上,与循环自适应相比,我们的算法可以进一步提高工作负载性能10.8%,与传统的固定功率预算控制相比,至少提高43%。本文通过使用可再生能源,在最大限度地减少计算系统的碳足迹方面迈出了第一步。我们期望本文提出的新型联合优化技术将有助于建立一个真正可持续的高性能计算环境。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
SolarCore: Solar energy driven multi-core architecture power management
The global energy crisis and environmental concerns (e.g. global warming) have driven the IT community into the green computing era. Of clean, renewable energy sources, solar power is the most promising. While efforts have been made to improve the performance-per-watt, conventional architecture power management schemes incur significant solar energy loss since they are largely workload-driven and unaware of the supply-side attributes. Existing solar power harvesting techniques improve the energy utilization but increase the environmental burden and capital investment due to the inclusion of large-scale batteries. Moreover, solar power harvesting itself cannot guarantee high performance without appropriate load adaptation. To this end, we propose SolarCore, a solar energy driven, multi-core architecture power management scheme that combines maximal power provisioning control and workload run-time optimization. Using real-world meteorological data across different geographic sites and seasons, we show that SolarCore is capable of achieving the optimal operation condition (e.g. maximal power point) of solar panels autonomously under various environmental conditions with a high green energy utilization of 82% on average. We propose efficient heuristics for allocating the time varying solar power across multiple cores and our algorithm can further improve the workload performance by 10.8% compared with that of round-robin adaptation, and at least 43% compared with that of conventional fixed-power budget control. This paper makes the first step on maximally reducing the carbon footprint of computing systems through the usage of renewable energy sources. We expect that the novel joint optimization techniques proposed in this paper will contribute to building a truly sustainable, high-performance computing environment.
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