Lin Jiang , Anthony Dowling, Yu Liu, Ming-C. Cheng
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引用次数: 0
摘要
针对多核 CPU 的热仿真,提出了一种基于适当正交分解(POD)和 Galerkin 投影(EnPOD-GP)的集合数据学习方法,以提高先前开发的全局 POD-GP 方法(GPOD-GP)的训练效率和模型精度。GPOD-GP 生成一组基函数(或 POD 模式)来解释热行为,以响应整个芯片中动态功率图 (PM) 的变化,这需要大量计算才能涵盖所有功率源的可能变化。然而,EnPOD-GP 可获取多组 POD 模式,从而显著提高训练效率和效果,而且其仿真精度与任何动态 PM 无关。与有限元模拟相比,GPOD-GP 和 EnPOD-GP 的计算速度提高了 3 个数量级。对于内核数量较少的处理器,GPOD-GP 提供了一种更高效的方法。当需要高精度和/或更多内核的处理器时,EnPOD-GP 在训练工作量、仿真精度和效率方面更为可取。此外,对于任何随机时空功率激励,EnPOD-GP 产生的误差都可以精确预测。
Ensemble learning model for effective thermal simulation of multi-core CPUs
An ensemble data-learning approach based on proper orthogonal decomposition (POD) and Galerkin projection (EnPOD-GP) is proposed for thermal simulations of multi-core CPUs to improve training efficiency and the model accuracy for a previously developed global POD-GP method (GPOD-GP). GPOD-GP generates one set of basis functions (or POD modes) to account for thermal behavior in response to variations in dynamic power maps (PMs) in the entire chip, which is computationally intensive to cover possible variations of all power sources. EnPOD-GP however acquires multiple sets of POD modes to significantly improve training efficiency and effectiveness, and its simulation accuracy is independent of any dynamic PM. Compared to finite element simulation, both GPOD-GP and EnPOD-GP offer a computational speedup over 3 orders of magnitude. For a processor with a small number of cores, GPOD-GP provides a more efficient approach. When high accuracy is desired and/or a processor with more cores is involved, EnPOD-GP is more preferable in terms of training effort and simulation accuracy and efficiency. Additionally, the error resulting from EnPOD-GP can be precisely predicted for any random spatiotemporal power excitation.
期刊介绍:
Integration''s aim is to cover every aspect of the VLSI area, with an emphasis on cross-fertilization between various fields of science, and the design, verification, test and applications of integrated circuits and systems, as well as closely related topics in process and device technologies. Individual issues will feature peer-reviewed tutorials and articles as well as reviews of recent publications. The intended coverage of the journal can be assessed by examining the following (non-exclusive) list of topics:
Specification methods and languages; Analog/Digital Integrated Circuits and Systems; VLSI architectures; Algorithms, methods and tools for modeling, simulation, synthesis and verification of integrated circuits and systems of any complexity; Embedded systems; High-level synthesis for VLSI systems; Logic synthesis and finite automata; Testing, design-for-test and test generation algorithms; Physical design; Formal verification; Algorithms implemented in VLSI systems; Systems engineering; Heterogeneous systems.
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