A parallel fast transform-based preconditioning approach for electrical-thermal co-simulation of power delivery networks

Konstantis Daloukas, Alexia Marnari, N. Evmorfopoulos, P. Tsompanopoulou, G. Stamoulis
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引用次数: 4

Abstract

Efficient analysis of massive on-chip power delivery networks is among the most challenging problems facing the EDA industry today. Due to Joule heating effect and the temperature dependence of resistivity, temperature is one of the most important factors that affect IR drop and must be taken into account in power grid analysis. However, the sheer size of modern power delivery networks (comprising several thousands or millions of nodes) usually forces designers to neglect thermal effects during IR drop analysis in order to simplify and accelerate simulation. As a result, the absence of accurate estimates of Joule heating effect on IR drop analysis introduces significant uncertainty in the evaluation of circuit functionality. This work presents a new approach for fast electrical-thermal co-simulation of large-scale power grids found in contemporary nanometer-scale ICs. A state-of-the-art iterative method is combined with an efficient and extremely parallel preconditioning mechanism, which enables harnessing the computational resources of massively parallel architectures, such as graphics processing units (GPUs). Experimental results demonstrate that the proposed method achieves a speedup of 66.1X for a 3.1M-node design over a state-of-the-art direct method and a speedup of 22.2X for a 20.9M-node design over a state-of-the-art iterative method when GPUs are utilized.
输电网电-热联合仿真中一种基于并行快速变换的预处理方法
大规模片上供电网络的有效分析是当今EDA行业面临的最具挑战性的问题之一。由于焦耳热效应和电阻率的温度依赖性,温度是影响红外降的重要因素之一,是电网分析中必须考虑的因素。然而,现代输电网络的庞大规模(包括数千或数百万个节点)通常迫使设计人员在红外下降分析期间忽略热效应,以简化和加速模拟。因此,在红外跌落分析中缺乏焦耳热效应的准确估计,在电路功能的评估中引入了重大的不确定性。这项工作为当代纳米级集成电路中大规模电网的快速电-热联合模拟提供了一种新的方法。最先进的迭代方法与高效且极其并行的预处理机制相结合,从而能够利用大规模并行架构(如图形处理单元(gpu))的计算资源。实验结果表明,当使用gpu时,与最先进的迭代方法相比,该方法在3.1 m节点设计上实现了66.1X的加速,在20.9 m节点设计上实现了22.2X的加速。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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