Assessing the effects of data compression in simulations using physically motivated metrics

2013 SC - International Conference for High Performance Computing, Networking, Storage and Analysis (SC) Pub Date : 2013-11-17 DOI:10.1145/2503210.2503283

D. Laney, S. Langer, Christopher Weber, Peter Lindstrom, Al Wegener

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引用次数: 57

Abstract

This paper examines whether lossy compression can be used effectively in physics simulations as a possible strategy to combat the expected data-movement bottleneck in future high performance computing architectures. We show that, for the codes and simulations we tested, compression levels of 3-5X can be applied without causing significant changes to important physical quantities. Rather than applying signal processing error metrics, we utilize physics-based metrics appropriate for each code to assess the impact of compression. We evaluate three different simulation codes: a Lagrangian shock-hydrodynamics code, an Eulerian higher-order hydrodynamics turbulence modeling code, and an Eulerian coupled laser-plasma interaction code. We compress relevant quantities after each time-step to approximate the effects of tightly coupled compression and study the compression rates to estimate memory and disk-bandwidth reduction. We find that the error characteristics of compression algorithms must be carefully considered in the context of the underlying physics being modeled.

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使用物理激励指标评估模拟中数据压缩的效果

本文研究了有损压缩是否可以有效地用于物理模拟，作为一种可能的策略来对抗未来高性能计算架构中预期的数据移动瓶颈。我们表明，对于我们测试的代码和模拟，可以应用3-5X的压缩级别，而不会对重要的物理量造成重大变化。而不是应用信号处理误差指标，我们利用适合于每个代码的基于物理的指标来评估压缩的影响。我们评估了三种不同的模拟代码:拉格朗日激波-流体动力学代码，欧拉高阶流体动力学湍流建模代码和欧拉耦合激光-等离子体相互作用代码。我们在每个时间步之后压缩相关的量来近似紧耦合压缩的效果，并研究压缩率来估计内存和磁盘带宽的减少。我们发现压缩算法的误差特性必须在被建模的底层物理环境中仔细考虑。

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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2013 SC - International Conference for High Performance Computing, Networking, Storage and Analysis (SC)

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